Unit 5 - Plant & Animal Responses

Question 1

Herbivory

Answer 1

Consumption of plants

Question 2

Tropisms

Answer 2

plant responses in response to various stimuli

Question 3

Phototropisms

Answer 3

Influenced by light e.g. plants grow towards light to photosynthesise due to auxin moving unilaterally

Question 4

Geotropism

Answer 4

Influenced by gravity
Plants recieve unilateral gravitational stimulus (downwards)
Shoots are -vely geotropic and roots are +vely geotropic

Question 5

Thigmotropism

Answer 5

Influenced by touch

Shoots of climbing plants e.g. ivy winding around other plants or solid structures for support

Question 6

Chemotropism

Answer 6

Influenced by chemicals

Growth of polen tube towards ovum

Question 7

Plant hormones

Answer 7

Cytokinins
Abscisic acid (ABA)
Auxins
Giberellins 
Ethene

Question 8

Effects of cytokinins

Answer 8

Promote cell divison
Delay leaf senescence - increases shelf life
Overcome apical dominance - lateral growth
Promote cell expansion

Question 9

ABA

Answer 9

Inhibit seed germination and growth
Stimulate cold protective responses
Cause stomatal closure when the plant is stressed by low water availability

Question 10

Effect of auxins

Answer 10

Promote cell elongation in roots - low conc
Promote shoot growth/ demote root growth - high conc
Inhibit growth of side shoots
Inhibit leaf abscission
Selective weedkiller
Promote cell division in cambium

Question 11

Effect of gibberellins

Answer 11

Promote seed germination - break bud dormancy (works against ABA)
Promote growth of stems - elongation of internodes
Develop seedless fruit and fruit setting
Acts synergistically w/ auxin

Question 12

Effect of ethene

Answer 12

Promote fruit ripening - starch to sugar and breaks down chlorophyll and cell wall
Stimulates cells in abscission zone to expand and breaks cell wall causing leaf to fall off

Question 13

How do plants avoid herbivores

Answer 13

Tannins - phenolic compounds; toxic to herbivores and microorganisms
Alkaloids - make plants taste bitter
Mimosa leaves fold up in response to touch - scares insects

Question 14

Abscission in deciduous plants

Answer 14

Decreases production of auxin
More sensitive to ethene
Gene expression of enzymes in abcission zone
Cellulase breaks down cell walls in separation layer of abscission zone
Vascular bundles sealed off, fatty materials for neat, waterproof scar

Question 15

Mechanism of seed germination

Answer 15

Seed absorbs H2O and activates embryo
Begins to produce gibberellins
Gene expression –> produces amylases and proteases to break down starch food stores
Glucose is used as a respiratory substrate and in protein synthesis

Question 16

Mechanism of stomatal closure

Answer 16

Levels of soil water falls
Roots produce ABA
Transported and binds to guard cells 
Increases pH, charged particles move out 
Increases wp, water moves out 
Loss of turgor closes stoma

Question 17

Proof of gibberellins causing seed germination

Answer 17

Mutant varieties that lack gibberellin do not germinate but w/ external gibberellin they do
When gibberellin inhibitors are addeed to normal seeds they dont grow

Question 18

Apical Dominance Effect

Answer 18

Auxin produced at the apex, inhibits growth of lateral buds

Question 19

Experimental evidence for apical dominance

Answer 19

Removal of apical buds allows lateral bud to grow
Auxin/synthetic auxin placed on cut tip continues to inhibit the growth of side shoots

Plant 30 plants of same type, age, genotype and weight in same soil
Remove tip of 10 and apply auxin paste
Remove tip of another 10 and add paste w/out auxin
Leave last 10 as control
Sig. increase of no. of side shoots grown in first 10

Question 20

Recent research on apical dominance

Answer 20

Auxin stimulates production of ABA (inhibits growth)
When apex is removed as is the source of auxin, ABA levels decrease
Most cytokinins go to tip so when tip is removed cytokinins spread evenly around plant promoting growth

Question 21

Where does growth occur in plants

Answer 21

Apical meristems

Lateral bud meristems

Question 22

Mechanism of cell elongation by auxin

Answer 22

Tip produces auxins, diffuses down 
Promotes active transport of H+ into cell walls
Lowers pH, optimum pH for expansins
Breaks H bonds within cellulose
Reduces rigidity and H2O enters

Question 23

Confirming auxin as the hormone that causes growth

Answer 23

Impregnated agar blocks w/ diff conc. of auxin
Placed them on cut shoot tips
Same effects as in reg. shoots
Curvature is directly proportional to conc of auxin used

Question 24

Research supporting geotropism in shoots

Answer 24

Plants are grown on a slowly rotating drum (clinostat) so gravitational stimulus is applied evenly
Plants grow straight in both light and dark

Question 25

Research supporting geotropism in roots

Answer 25

Seeds are placed in petri dishes w/ moist cotton wool that are rotated 90 degrees as seedlings grow
Cover lid w/ oil - ensure no light is coming in
All petri dishes should be in same environment
Geotropic response in the roots can be seen every 2 hours

Question 26

Investigating role of gibberellin in stem elongation

Answer 26

Plant 40 plants
Water 20 plants normally
Water other 20 w/ diluted solution of gibberellins
Let all 40 grow for 28 days, measuring height every 7
Calculate rate at which plants grew

Question 27

IAA

Answer 27

Natural form of auxin responsible for +ve phototropism so plant bends towards light to phostosynthesise and grow taller and grows roots to reach water and nutrients
Light stimulus detected by tip of plant

Question 28

Central nervous system

Answer 28

Brain and spinal cord
Mostly relay neurones in brain
Mostly non-myelinated in brain and myelinated in spinal cord

Question 29

Role of peripheral nervous system

Answer 29

Ensure rapid comm between the sensory receptors, CNS and effectors

Question 30

Divisions of PNS

Answer 30

Sensory nerous systems

Motor nervous system

Question 31

Sensory nervous system

Answer 31

Neurons conduct action potentials from the sensory receptor into the CNS

Question 32

Divisions of motor nervous system

Answer 32

Autonomic

Somatic

Question 33

Somatic nervous system

Answer 33

Motor neurones that conduct action potentials to effectors that are under voluntary control e.g. skeletal muscles
Mostly myelinated neurones
One single motor neuone connecting CNS to effector

Question 34

Autonomic nervous system

Answer 34

Motor neurones that conduct action potentials to effectors that arent under voluntary control e.g. cardiac muscles
Mostly unmyelinated neurones
At least two motor neurones involved - connected at ganglia

Question 35

Divisions of autonomic nervous system

Answer 35

Sympathetic

Parasympathetic

Question 36

Ganglia in sympathetic system

Answer 36

Outside CNS, near spinal cord

Question 37

Ganglia in parasympathetic system

Answer 37

Closer to effector tissue

Question 38

Neurones in sympathetic system

Answer 38

Short pre-ganglionic neurones

Long post-ganglionic neurones

Question 39

Neurones in parasympathetic system

Answer 39

Long pre-ganglionic neurones

Short post-ganglionic neurones

Question 40

Neurotransmitter in sympathetic system

Answer 40

Noradrenaline

Question 41

Neurotransmitter in parasympathetic system

Answer 41

Acetylcholine

Question 42

Four sections of the brain

Answer 42

Cerebrum
Cerebellum
Medulla Oblongata
Hypothalamus and pituitary complex

Question 43

Cerebrum

Answer 43

Largest part of human brain
Two hemispheres connected by corpus callosum
Involved in control of speech and higher thought processes e.g. planning a task

Question 44

Cerebral cortex

Answer 44

Highly folded
Outer part of cerebrum
Involved in higher thought e.g. overriding reflexes, conscious thought, intelligence and reasoning

Question 45

What is the cerebral cortex divided into

Answer 45

Sensory areas - recieve impulses from sensory neurones
Motor areas - send impulses out to effectors
Association areas - link info and coordinate approriate respnse

Question 46

Cerebellum

Answer 46

Controls muscular movement and balance
Connected to cerebrum by pons
Coordination of posture

Question 47

Medulla oblongata

Answer 47

Controls involuntary processes e.g. heart rate and breathing rate
Has specialised centres that recieve info from internal receptors and adjust breathing and heart rate accordingly

Question 48

Hypothalamus and pituitary complex

Answer 48

Organises homeostatic responses and controls various physiological processes
Info is recieved from hypothalamus and hormones are released via the pituitary gland (controls endocrine system)

Question 49

Reflex reactions

Answer 49

Responds to changes in the environment but not involving the brain
Sensory –> relay –> motor
Brain may be informed but doesn’t coordinate
Survival; fast, involuntary and not learned (innate)

Question 50

Cranial reflex

Answer 50

Nervous pathway passes through the brain

Question 51

What makes something an reflex arc

Answer 51

Receptor and effector in same place

Question 52

Blinking reflex

Answer 52

Cranial reflex
Corneal - object toucing eyes
Optical - Light hitting back of eye (retina)

Question 53

Patnway for corneal blinking reflex

Answer 53

Receptor
Sensory neurone on cornea
Sensory centre on pons
Non-myelinated relay neuron passes action potential to motor neurone
Motor neurone passes out of brain to facial muscles

Question 54

If the corneal blinking reflex is to be overridden

Answer 54

Sensory neurone on cornea
Myelinated relay neurones inform brain
Allows reflex to be overriden (inhibitory neurone) - faster so reflex can be overriden before it happens

Question 55

Knee-jerk reflex

Answer 55

Spinal reflex
Unexpected stretching of quadraceps –> detected by muscle spindles –> causes a reflex reaction (no relay neurone) –> quadraceps contract

Question 56

Spinal reflex

Answer 56

Involves the spinal chord rather than the brain

Question 57

Muscle spindles

Answer 57

Stretch receptors that detect increase in muscle length

Question 58

Class of hormones

Answer 58

Steroid - produced in reproductive organs and adrenal cortex
Peptide - insulin, ADH, adrenaline

Question 59

Hypothalamic - anterior axis

Answer 59

Hypothalamus releases hormones (releasing factors)
Pass down a portal vessel to anterior pituitary gland
Anterior pituitary gland releases tropic hormones e.g. for thyroid and adrenal

Question 60

Tropic hormones

Answer 60

These stimulate other endocrine glands

Question 61

Mechanism of steroid hormones

Answer 61

Steroid hormone combines w/ steriod receptor in cytoplasm
Hormone-receptor complex enters nucleus
Complex binds to receptor sites on DNA, activating mRNA transcription
mRNA leaves nucleus
Ribosome translates mRNA into new protein in cytoplasm

Question 62

Mechanism of peptide hormones

Answer 62

Adrenaline in the blood binds to membrane bound receptor
Stimulates G-protein to activate Adenyl cyclase
Converts ATP to cAMP
cAMP acts as second messenger by moving into the cell cytoplasm and causing an effect

Question 63

Thyroxin

Answer 63

Increases metabolic rate in most cells

Question 64

How is thryoxin released

Answer 64

Hypothalamus releases TRH
Travels to anterior pituitary gland and releases TSH
Travels to thyroid through portal vessel and releases thyroxine

Question 65

TRH

Answer 65

Thyrotropin releasing hormone

Question 66

TSH

Answer 66

Thyroid stimulating hormone

Question 67

How are glucocorticoids (cortisol) released

Answer 67

Hypothalamus releases CRH
Travels to anterior pituitary gland and releases ACTH
Travels to adrenal cortex through portal vessel and releases cortisol

Question 68

Cortisol

Answer 68

Released as a response to chronic stress

Stimlates breakdoen of glycogen

Question 69

Coordination of flight or fight

Answer 69

Sensory input
Action potential travels to sensory centres (cerebrum)
Signals passed to association areas
If a threat is recognised, cerebrum stimulates hypothalamus
Hypothalamus stimulates symapthetic nervous system and stimulates release of hormones from anterior pituitary gland

Question 70

How is the fight or flight response formed

Answer 70

Hypothalamus activates sympathetic nervous system
Impulses activate glands and smooth muscle
Activated adrenal medulla
Secretion of adrenaline into the bloodstream
Hypothalamus also secretes releasing factors e.g. CRH and TRH

Question 71

CRH

Answer 71

Corticotropic releasing hormone

Question 72

ACTH

Answer 72

Adrenocorticotropic hormone

Question 73

Physiological changes in fight or flight response

Answer 73

Pupils dilate - more light enters eyes, retina becomes more sensitive
Heart rate and bp increase
Ventilation depth and rate increases
Less digestion
Blood glucose increases
Metabolic rate increase - faster coversion of glucose to ATP
Endorphins released in brain
Erector pili muscles in the skin contract

Question 74

Why do erector pili muscles stand up in fight or flight response

Answer 74

Hairs/ fur stands up - signs of aggression

Question 75

Why are endorphins released in the fight or flight response

Answer 75

Wounds inflicted don’t prevent activity

Question 76

Why must plants be able to respond to their environment

Answer 76

Cope w/ changing conditions

Avoid antibiotic stress

Question 77

How does auxin cause cell elongation (2 marks)

Answer 77

Loosens rigid cellulose framework

Osmotic uptake of water allows cell elongation

Question 78

Why do cut plants w/ agar blocks w/ auxin placed on the rhs bend to the lhs

Answer 78

Auxin produced at tip
Diffuses laterally to rhs
Cells on rhs exhibit greater elongation
Bending to the left

Question 79

How does auxin act as a selective weedkiller

Answer 79

Rapid cell elongation so plant grows too quickly
No extra lignified tissue
Stem collapses or loss of extra water from leaves

Question 80

What happens when the apex is removed from a plant

Answer 80

Once apex is removed, auxin production stops
Apical dominance is stopped
Lateral growth is not inhibited and lateral buds develop

Question 81

Types of muscle

Answer 81

Skeletal (voluntary)
Cardiac
Involuntary (smooth)

Question 82

Voluntary (skeletal muscle)

Answer 82

Striated 
Multinucleate 
Regularly arranged —> contraction in one direction 
Attached to bone by tendon 
Tubular 
Nerves from peripheral, somatic (rapid)

Question 83

Cardiac muscle

Answer 83

Specialised striated (parallel myofibrils)
Branched fibres
Uninucleated
Cross bridges allow simultaneous contraction
Dark bands - intercalated discs
Nerves from autonomic nervous system

Question 84

Involuntary (smooth muscle)

Answer 84

Non striated
Nerves from autonomic nervous system
No reg. arrangement - diff cells can contract in diff directions
Fibres are spindle shaped and uninucleated
Used in hollow organs (peristalsis)

Question 85

Sarcolemma

Answer 85

Plasma membrane that encloses bundles of muscle fibre

Question 86

Why may the sarcolemma fold in

Answer 86

Spread impulse throughout sarcoplasm

Contract at the same time

Question 87

Sarcoplasm

Answer 87

Shared cytoplasm within muscle fibres

Question 88

How are muscle fibres formed

Answer 88

Fusion of several embryonic muscle cells - gap between adjacent cells would be a weakness
(That’s why it’s multinucleate)

Question 89

Sarcoplasmic reticulum

Answer 89

Modified version of ER

Provides strength and stored Ca^2+

Question 90

Protein filaments

Answer 90

Myosin

Actin

Question 91

Muscle organisation

Answer 91

Muscle 
Fascicles 
Muscle fibres 
Myofibrils 
Protein filaments

Question 92

Connective tissue

Answer 92

Tendons

Question 93

Light band (I)

Answer 93

Thin actin held together by Z line

Question 94

Dark band (A)

Answer 94

Both actin and myosin
Entire length of myosin
Myosin held together by M line

Question 95

M line

Answer 95

Midpoint of myosin

Has no heads

Question 96

Z line

Answer 96

Found at the centre of each light band

Question 97

Sarcomere

Answer 97

Functional unit of muscle
From one Z line to another
Sub unit of myofibrils

Question 98

Why is muscle considered a tissue

Answer 98

Muscle fibre
Blood vessels
Nerves
Connective cells

Question 99

Characteristics of sliding filament model

Answer 99

Z lines get closer
Sarcomeres shortens
I band narrows
H zone narrows

Question 100

What does simultaneous contraction of several sarcomeres allow

Answer 100

Myofibrils and then muscle fibres to contract —-> enough to pull a bone

Question 101

Neuromuscular junction

Answer 101

Action potential arriving at axon of motor neurone opens VG Ca2+ to flood into tip
Vesicles of acetylcholine to move towards membrane & fuse
Acetylcholine diffuses across synapse and binds to receptors on sarcolemma
Na+ channels open and wave of depolarisation passes down transverse tubules
Passes to SR which releases Ca2+ into the sarcoplasm

Question 102

Cross bridge muscle contraction cycle

Answer 102

Tropomyosin is blocking myosin binding site in actin
Ca2+ binds to troponin causing a conformational change, tropomyosin moves
Myosin heads bind to actin, forming cross bridges between filaments
Myosin heads move, pulling the actin filament. ADP and Pi are released during the power strike
A new ATP molecule attaches to myosin head, breaking cross bridge
ATP hydrolyses and myosin head returns to its orig. position

Question 103

Where does SR get Ca^2+

Answer 103

Active absorption from sarcoplasm

Question 104

Supply of ATP for muscular contraction

Answer 104

Aerobic respiration - oxidative phosphorylation
Anaerobic respiration - glycolysis
Glycogen —> glucose
Creatine phosphate can combine w/ ADP to form ATP

Question 105

Where is creatine phosphate found

Answer 105

Sarcoplasm

Question 106

Supply of energy of slow twitch muscle

Answer 106

Aerobic respiration

Question 107

Supply of energy for fast twitch muscle

Answer 107

Anaerobic respiration

Question 108

Where is the cardiovascular centre

Answer 108

Medulla oblongata - this alters the excitation wave frequency

Question 109

Frequency of heart excitation

Answer 109

60-80 bpm

Question 110

What is the heart rate regulated by

Answer 110

SAN

Nerves connect cardiovascular centre to the SAN

Question 111

Nerves involved in controlling heart rate

Answer 111

Accelerans

Vagus

Question 112

Accelerans

Answer 112

Causes release of noradrenaline at SAN 
Increases HR (sympathetic)

Question 113

Vagus nerves

Answer 113

Causes release of acetylcholine at SAN, reduces HR (parasympathetic)

Question 114

Sensory inputs that increase HR

Answer 114

Increased muscle movement (muscle stretch receptors)
Decrease in pH (chemoreceptors)
Adrenaline in blood

Question 115

Sensory inputs that decrease HR

Answer 115

Increase in bp (stretch receptors - carotid sinus)

Decrease in dissolved CO2 (chemoreceptors)

Question 116

Why do plants kept in the dark grow taller than those in the light

Answer 116

Auxin is more present in the dark

Question 117

Plant growth substances vs animal hormones

Answer 117

Hormones travel faster in animals
Synthesised in endocrine glands vs cells sites
Slow acting in plants vs fast acting in animals

Question 118

Why is temp controlled in investigations on effect of plant hormones

Answer 118

So temp does not affect results as temp affects enzyme activity

Question 119

Why are monkeys used for human research

Answer 119

Closely related
Both primates
Similar physiology

Question 120

Actions of parasympathetic nervous system

Answer 120

Increases blood flow to digestive system, allows peristalsis 
Decreases HR 
Decreases airway diameter 
Sexual arousal 
Constricts pupils

Question 121

Why is glycogen found in striated muscle

Answer 121

Glycogenolysis
Glucose can undergo glycolysis to produce ATP
Energy storage

Question 122

Uses of mitochondria in muscular contraction

Answer 122

ATP attaches to ATPase on the myosin head
Hydrolysis to release ADP and Pi during power stroke, allows myosin heads pull the actin filaments
Needed for myosin head to detach
Protein synthesis
Ca 2+ pumps in SR

Question 123

Internal organs affected by SNS/PNS

Answer 123

Heart
Lungs
Liver
Intestines

Question 124

How is the heart affected in the peripheral nervous system/sympathetic nervous system

Answer 124

peripheral NS: Slow HR
sympathetic NS: fast HR

Question 125

How are the lungs affected by the PNS/SNS

Answer 125

Shallow breaths vs deep breaths

Question 126

How is the liver affected by the PNS/SNS

Answer 126

Glucose take up (glycogenesis) vs glucose used up (glycolysis)

Question 127

How is the stomach affected by the PNS/SNS

Answer 127

More peristalsis vs. less

Question 128

How does the SNS affect smooth muscle

Answer 128

Alters blood flow to increase bp
Vasoconstriction 
Peristalsis slows down 
Relaxes in airways (increases diameter)
Pupils dilate

Question 129

How does the SNS affect cardiac muscle

Answer 129

Heart beats faster

Beats w/ more force

Question 130

How does SNS affect voluntary muscles

Answer 130

Glycogenolysis in muscles for priming
Diaphragm contracting faster
More blood flow to skeletal muscle –> respiration

Question 131

Long term effects of chronic stress

Answer 131

Cardiovascular problems due to high bp

Suppression of immune system leads to susceptibility to disease

Question 132

Photoperiodism

Answer 132

Plants’ sensitivity to a lack of light, affects several diff plant responses e.g. flowering

Question 133

Phytochrome

Answer 133

Light sensitive pigment that affects the sensitivity of plants to light
Exists in two forms, Pt and Pft

Question 134

How do plants prevent freezing

Answer 134

Cytoplasm and vacuole contain sap that lowers the freezing point
Produce biological molecules (excluding lipids) to prevent cytoplasm freezing or protect cells from damage if they do freeze

Question 135

Commercial uses of plant hormones

Answer 135

Ethene to control ripeneing 
Hormone rooting powders and micropropagation 
Auxin to produce seedless fruit 
Cytokinins to prevent aging 
Gibberellins to improve size and shape

Question 136

Transverse tubules

Answer 136

Extensions into sarcolemma

Question 137

Factors affecting stomatal closure

Answer 137

Temperature

Water availability

Question 138

How does increases in temp affect stomata

Answer 138

Release of ABA decreases
Stomata open
Allows plant to cool through water evaporation

Question 139

How does decrease in water availability affect stomatal

Answer 139

Increased release of ABA
Stomata close
Reduces water loss through transpiration

Question 140

How do gibberellins cause stem elongation

Answer 140

Promote cell elongation - by loosening cell walls

Promote cell division - producing proteins that control the cell cycle