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Transcript
INCLUDING EXAMINERS COMMENTS
R3101
PLANT TAXONOMY, STRUCTURE & FUNCTION
Level 3
Wednesday 8 February 2017
09:30 – 11:10
Written Examination
Candidate Number:………………………………………………………………….
Candidate Name:…………………………………………………………………….
Centre Number/Name:………………………………………………………………
IMPORTANT – Please read carefully before commencing:
i)
The duration of this paper is 100 minutes;
ii)
ALL questions should be attempted;
iii)
EACH question carries 10 marks;
iv)
Write your answers legibly in the spaces provided. It is NOT necessary
that all lined space is used in answering the questions;
v)
Use METRIC measurements only;
vi)
Use black or blue ink only. Pencil may be used for drawing purposes only;
vii)
Where plant names are required, they should include genus, species and
where appropriate, cultivar;
viii)
Where a question requires a specific number of answers; only the first
answers given that meet the question requirement will be accepted,
regardless of the number of answers offered;
ix)
Please note, when the word ‘distinct’ is used within a question, it means
that the items have different characteristics or features.
.
Ofqual Unit Code H/505/2966
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ANSWER ALL QUESTIONS
MARKS
Q1
a)
6
Describe the structural characteristics of conifers.
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b)
State FOUR ways by which the reproduction in conifers differs from that of
ferns by completing the table below.
Conifers
4
Ferns
1
2
3
4
Total Mark
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3
MARKS
Q2
a)
State what is meant by the term ‘tissue’.
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b)
Explain how the structure of epidermal tissue enables it to fulfil THREE distinct
functions.
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Q3
a)
State the optimum conditions for prolonging the storage life of fruit.
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b)
State the difference between modified and controlled atmospheres used in
fruit storage.
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c)
Explain how control of the gaseous atmosphere affects fruit storage life.
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Q4
a)
State the difference between endogenous and synthetic plant growth
regulators (PGRs).
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b)
State what is meant by the term ‘apical dominance’.
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c)
Describe how endogenous PGRs control apical dominance.
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Q5
a)
Name the type of fruit shown below, giving ONE NAMED plant example.
Type of fruit:…………………………………………………………………………………
Plant example:………………………………………………………………………………
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b)
Name and describe the characteristics of EACH of the structures labelled
A - D on the diagram in part a), by completing the table below.
Name
Characteristic
A
B
C
D
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Q6
a)
List FOUR environmental conditions that can affect water loss from plants.
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b)
Describe TWO ways by which bog plants are adapted to their environment
giving a NAMED plant example for EACH.
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Q7
Describe the use of supplementary and replacement lighting, by completing
the table below.
Supplementary lighting
Replacement lighting
Meaning of
term
2
Horticultural
situation
where used
2
Choice of
lamp
2
Two distinct
reasons for
choice
of lamp
1
1
2
2
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Q8
a)
Differentiate between the terms ‘genus’ and ‘species’.
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MARKS
b)
State what is meant by the following types of plant hybrid giving a NAMED
plant example for EACH:
i) intergeneric;
ii) interspecific;
iii) graft.
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2
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Q9
a)
In a plant, sucrose is transported from source to sink.
Give an example of:
i)
ii)
a source;
a sink.
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b)
Explain how the following processes enable sucrose to be transported:
i) phloem loading and unloading;
ii) mass flow.
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Q10
Compare how flowers are adapted for pollination by moths and butterflies, by
completing the table below:
Moths
Butterflies
Plant example
2
Flowering time
2
Inflorescence/ flower
structure
2
Scent
2
Flower colour
2
Total Mark
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©These questions are the property of the Royal Horticultural Society.
They must not be reproduced or sold.
The Royal Horticultural Society, Wisley, Woking, Surrey GU23 6QB.
Charity Registration Number: 222879/SC038262
24
R3101
PLANT TAXONOMY, STRUCTURE & FUNCTION
Level 3
Wednesday 8 February 2017
Candidates Registered
Candidates Entered
Candidates Absent/Withdrawn
Candidates Deferred
136
118
17
1
Total Candidates Passed
Passed with Commendation
Passed
Failed
85%
48%
37%
15%
Senior Examiner’s Comments
On the whole this paper was well answered with the majority of candidates attempting and completing
all the questions. The following guidelines should be of help to future candidates.
1. Where named plant examples are asked for, full botanical names (genus and species) are
required to achieve full marks. Common names will not be given a mark.
2. Use the command statements e.g. list or name (single words only), state (a few sentences),
describe or explain (a fuller answer) together with the mark allocation, to judge the depth of the
answer. Half marks are often allocated where the basic information given is correct but needs
further qualification to gain the full mark.
3. Where a number of answers are specified in the question, the examiner will not select correct
answers from a list e.g. if the question states ‘State’ TWO plant names’, only the first two
names given will be marked.
4. Labels on diagrams should be correctly positioned to avoid ambiguity and diagrams should be
clearly drawn and annotated. No marks will be awarded for artistic merit.
5. Candidates should use unambiguous plant examples as reference sources from, for example,
the RHS Find a Plant Service available on the RHS Website.
25
MARKS
Q1 a) Describe the structural characteristics of conifers.
6
Q1 b) State FOUR ways by which the reproduction in conifers differs from that of ferns by
completing the table below.
4
Conifers
Ferns
1
2
3
4
Q1 a) Marks were awarded for naming structural characteristics and for describing them, including
xerophytic adaptations. For example, needle-shaped leaves, sunken stomata, xylem tissue
made up of tracheids, resin ducts.
Many candidates gave reproductive characteristics rather than structural ones.
Q1 b) Some candidates found it difficult to give paired statements comparing conifer and fern
reproduction e.g.


Conifers disperse by means of seeds whereas ferns disperse by means of spores,
The conifer male gamete is transferred by wind in pollen whereas the fern male gamete
is transferred in sperm which swim in water.
Most candidates recognised that ferns require water for reproduction whereas conifers do not.
Many confused the role of spores in ferns and pollen in conifers. Fern spores give rise to a
prothallus which produces the male and female gamete. They are not the gamete itself.
A number of candidates wrongly stated that ferns produce pollen or undergo pollination.
All plants undergo alternation of generations in their life cycle but the gametophyte phase is
much reduced in conifers compared to ferns.
Negative statements e.g. conifers produce seeds whereas ferns do not were not fully credited.
26
MARKS
Q2 a) State what is meant by the term ‘tissue’.
1
Q2 b) Explain how the structure of epidermal tissue enables it to fulfil THREE
distinct functions.
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a) Almost all candidates were able to state that a tissue is a group of cells performing a specific
function. Information beyond this was not required.
b) Candidates who scored well approached this part of the question by identifying three distinct
functions then went on to describe the related epidermal structure e.g.


Reducing water loss from transpiration by having tightly packed epidermal cells with no
air spaces between them, a waterproof cuticle, leaf hairs which increase humidity close
to the leaf or the ability to close stomata.
Enabling light penetration for photosynthesis in underlying cells due to epidermis being
one cell thick and not containing chloroplasts.
The question asked about the structure and function of epidermis not the periderm.
Epidermis does not contain sclerenchyma, collenchyma or chloroplasts and stomata do not take water
into the leaf for photosynthesis.
Several candidates conflated protection and control of water loss which are different functions.
MARKS
Q3 a) State the optimum conditions for prolonging the storage life of fruit.
4
Q3 b) State the difference between modified and controlled atmospheres used in fruit storage.
2
Q3 c) Explain how control of the gaseous atmosphere affects fruit storage life.
4
a) It was generally known that low temperatures and oxygen levels and high carbon dioxide levels
prolong the storage life of fruit. Most candidates were able to state four conditions for optimising
storage life such as increasing CO2, decreasing O2, cool temperature, suitable humidity (neither
dry nor high) and good fruit quality.
Storage in the dark is not necessary.
Many candidates gave information about storage conditions in this section which was more
appropriate to part c).
b) Very few candidates knew the difference between modified and controlled atmosphere storage
which relates to the gaseous atmosphere surrounding produce. In modified atmosphere storage
produce is sealed e.g. in a package with no further manipulation. In controlled atmosphere
storage, generally large scale stores, the atmosphere changes and is continuously monitored
and modified during the storage period.
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c) Where candidates noticed that this question was about the gaseous atmosphere i.e. oxygen,
carbon dioxide, ethylene, nitrogen levels and relative humidity, rather than other storage
conditions, they scored highly.
Marks were awarded for stating how the levels of these gases affect storage and the methods
used to control them.
Marks were also awarded for demonstrating an understanding of the effects of the gaseous
atmosphere on the progression through ripening and senescence and how this is linked to
respiration and ethylene production.
The relationship between humidity, water loss and development of rots was also relevant.
MARKS
Q4 a) State the difference between endogenous and synthetic plant growth regulators (PGRs).
2
Q4 b) State what is meant by the term ‘apical dominance’.
2
Q4 c) Describe how endogenous PGRs control apical dominance.
6
a) Almost all candidates were able to state that endogenous PGRs are produced within the plant
whereas synthetic PGRs are manufactured and applied externally.
b) Better candidates provided a succinct definition of apical dominance i.e. the suppression of later
growth by the apical but, rather than describing the effects of apical dominance e.g. the type of
branching in trees.
Many candidates described the mechanism of apical dominance here rather than in part c).
c) Most candidates were able to state that auxin promotes apical dominance and that cytokinin acts
antagonistically to it. More than one PGR needed to be mentioned for full marks. Gibberellin is not
involved in apical dominance since it only acts to stimulate lateral growth once the apical but is
removed but does not overcome apical dominance itself. Ethylene is probably involved in inhibiting
auxin transport.
Any suitable theory was accepted the most popular being the attraction of sugars and cytokinin,
produced in the leaves, to the apical bud which prevents the axillary bud from breaking.
Auxin is produced in the apical bud/meristem and translocated to the region behind it. Auxin
movement is polar, with the result that the apical dominance effect weakens down the stem.
Several candidates described tropisms rather than apical dominance.
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MARKS
Q5
a)
i) Name the type of fruit shown below, giving a NAMED plant example:
2
Type of fruit:………………………………………………………
Plant example:……………………………………………………
b) Name and describe the characteristics of EACH of the structures labelled A - D
on the diagram in part a), by completing the table below.
Name
8
Characteristic
A
B
C
D
a) The majority of candidates correctly identified the fruit as a drupe and were able to give a suitable
example, the most popular being any Prunus spp.
b) Most candidates correctly identified the labelled parts specifically as epicarp (not the epidermis or
pericarp), mesocarp, endocarp and seed and were able to describe a characteristic of each.
The seed contains the embryo (it is not the embryo itself).
Drupes are endospermic seeds.
29
MARKS
Q6
a) List FOUR environmental conditions that can affect water loss from plants.
4
b) Describe TWO ways by which bog plants are adapted to their environment giving
a NAMED plant example for EACH.
6
a) Many candidates described environmental conditions rather than just listing them so used
up valuable time.
Full marks were awarded for relative humidity (not just humidity), temperature, light and
windspeed (not just wind).
b) Marks were awarded for suitable named bog plants such as Taxodium distichum or Gunnera
manicata rather than aquatic plants such as Nymphaea spp. Insectivorous plants such as Drosera
spp. were also appropriate examples.
Most candidates mentioned adaptations such as pnematophores and aerenchyma and were able to
describe these and their function of channeling oxygen down to the submerged roots from the aerial
parts of the plants. Other mechanisms included physiological adaptations such as conversion of
ethanol to non-toxic malic acid, digestion of insects to supply nitrogen and other nutrients which are
unavailable in waterlogged soils and prop roots to improve stability.
Some candidates described large leaves as in Gunnera being a mechanism to remove excess water
through increased transpiration but large leaves exist simply because there is plenty of water so
plants can optimise their leaf area for photosynthesis rather than this being an adaptation enabling
them to live in waterlogged soils.
30
Q7
Describe the use of supplementary and replacement lighting, by completing the table below.
Supplementary
lighting
Replacement
lighting
MARKS
Meaning of
term
Horticultural
situation where
used
Choice of lamp
2
2
2
Two distinct
reasons for
choice
of lamp
4
Describing a horticultural situation, supplementary lighting is used for example in glasshouses to boost light
levels or extend the daylight hours whereas replacement lighting is used in growth rooms or cabinets. Marks
were also awarded for mentioning suitable crops for each situation e.g. bedding plants vs. micropropagation.
Replacement lighting is not used for AYR Chrysanthemums. Better candidates were able to give two distinct
and suitable lamps and justify their choice. For example, High Pressure Sodium lamps are widely used in
glasshouses for supplementary lighting because they can have a suitable spectral quality, they generate heat
so can be used for heating, and are economical. LEDs can be used for replacement lighting as they generate
little heat and can be used near the crop, their spectral quality can be manipulated easily, the rig is small so
there is less shading and they are economical and long lasting.
High Pressure Mercury and LEDs were also accepted for supplementary lighting and fluorescent lamps and
Low Pressure Mercury for replacement lighting.
MARKS
Q8
a) Differentiate between the terms ‘genus’ and ‘species’.
4
b) State what is meant by the following types of plant hybrid giving a NAMED plant example for
EACH:
i) intergeneric;
ii) interspecific;
iii) graft.
2
2
2
a) Candidates needed to state that a genus is a group of species (not just plants) for full marks.
Marks were awarded for stating the position of genus and species in the taxonomic hierarchy
and that plants within a species can interbreed. Many stated that subsequent offspring are ‘true
to type’ but this is not always the case.
b) Most candidates were able to define intergeneric and interspecific hybrids and give a correct example
for each.
Very few understood that a graft hybrid is new tissue which arises out of the grafting together of two
plants and contains genetic material from both. Many candidates incorrectly described grafting e.g. in
apples.
31
MARKS
Q9
a) In a plant, sucrose is transported from source to sink.
Give an example of:
i)
ii)
2
a source;
a sink.
b) Explain how the following processes enable sucrose to be transported:
i)
ii)
phloem loading and unloading;
mass flow.
4
4
a) Most candidates understood that a source is where carbohydrates are made e.g. mature leaves and a
sink is where they are used e.g. apical buds. Perennating organs such as tubers and bulbs act as
sinks and sources at different times of year so candidates who used these examples only obtained
full marks if this was stated correctly.
b) The answers to parts i) and ii) were often mixed up in this part of the question.
Better candidates described phloem loading and unloading in terms of the movement of sugars into
and out of the phloem sieve tubes via transfer cells. This involves active transport, across the cell
membrane on protein carries at the source (loading) and removal (unloading ) at the sink which can
be active or passive.
Mass flow is the movement of sugars through the phloem from source to sink under a pressure
gradient. Many accurately described how sugars loaded into the phloem increase the sugar
concentration and cause water to move into the sieve tubes by osmosis setting up a positive
hydrostatic pressure. Water then carries the sugar dissolved in it along the phloem under this
pressure to where it is unloaded. This continues as long as sugars are loaded and unloaded at each
end of the phloem tissue. Some candidates described transpiration pull in the xylem and focussed on
water circulation rather than sugar transport. Munch’s mass flow hypothesis was sometime described
with a diagram and marks were awarded as long as this was related to what was happening in the
plant.
32
MARKS
Q10
Compare how flowers are adapted for pollination by moths and butterflies, by
completing the table below:
Moths
10
Butterflies
Plant Example
Flowering Time
Inflorescence /
Flower Structure
Scent
Flower Colour
This question was generally well answered and better candidates made paired comparisons under each
heading.
Some plant examples were rather obscure and could not be verified.
Flowering time could relate to time of opening during the day with moth pollinated flowers or the time of year
for the chosen plant example.
Details of flower structure and/or inflorescence structure (rather than type) together with a description
explaining how this was an advantage to a moth or butterfly gained full marks.
Presence and absence of scent together with scent strength and character were awarded marks, as were
specific flower colours.
33