2101 - Leaves

Question 1

Main Functions of a Leaf

Answer 1

Provide a site for Photosynthesis.
Regulate Transpiration.
Allow Gaseous Exchange.

Arrise from Nodes on the stem as it grows. Do not arrive from anywhere else.

Question 2

Physiological Functions

Answer 2

Convert Light, CO2 and H2O into sugars via Photosynthesis.

Regulate Transpiration, thus the uptake of water and nutrients by the plant.

Control the absorption and release of CO2 and O2 via Gaseous Exchange.

Question 3

Leaf parts

Answer 3

Axially bud (on stem)
Petiole (stalk)
Leaf Base
Lamina (leaf blade)
Margin (the edge)
Midrib (main vein)
Lateral Veins
Sub Lateral Veins

Question 4

Leaf Characterisation

Answer 4

Shape
Size
Colour
Margin
Venation
Division of the Leaf Blade
Arrangement on the Stem

Question 5

Internal Structure of a Leaf

Answer 5

Cuticle
Upper Epidermis
Pallisade Mesophyl
Spongy Mesophyl
Lower Epidermis
Stomata
Sub-Stomatal Air Chamber
Guard Cells

Question 6

Internal Structure of a Leaf - Epidermis

Answer 6

Single layer of cells, do not contain chlorophyll, but produce Waxy layer cuticle.
Lower epidermis contains the stomata.
Relatively transparent.

Question 7

Internal Structure of a Leaf - Cuticle

Answer 7

Waxy layer protects against pests, disease and water loss.

Can be thick or thin depending on the plant.

Question 8

Internal Structure of a Leaf - Palisade Mesophyll

Answer 8

Tightly packed oblong/vertically arranged cells just under the upper epidermis.
Large number of Chloroplasts for optimum Photostynthesis.

Question 9

Internal Structure of a Leaf - Spongy Mesophyll

Answer 9

Parenchyma cells below the Palisade cells.
Typically less Chloroplasts than Palisade cells.
Loosely packed to facilitate the diffusion of Oxygen, Carbon Dioxide and water vapour.

Question 10

Internal Structure of a Leaf - Stomata

Answer 10

Breathing pores predominantly in the lower epidermis in Dicots. Allow for Gaseous exchange.

Controlled by Guard Cells in response to light levels and water content of the plant.
Under Active and Passive control.

Ions can be pumped into and out of the guard cells causing them to lose or gain water (osmosis) and open or close.

Water loss by dehydration (loss of Turgor) can also close the stomata. Inhibiting gaseous exchange therefore further water loss via Transpiration.

Question 11

Leaf Arrangement on Stem - Opposite, Alternate, Whorled.

Answer 11

Opposite - Each node has a pair of leaves.
Cornus spp.

Alternate - Each node has a single leaf, the adjacent nodes point in different directions.
Salix spp.

Whorled - Node has three or more leaves.
Galium spp.

Question 12

Leaf Arrangement - Simple vs Compound

Answer 12

Simple - Single undivided blade or Lamina. Cannot be sub-divided into leaflets.
May be formed of lobes (Quercus) but gaps do not reach the Mid Rib.

Compound - Blade is divided into several leaflets. Identified by the lack of Axially bud. (Midrib may be called Rachis)

Question 13

Simple, Lobed, Palmately Compound, Pinnately Compound

Answer 13

Simple - Fagus syllabic
Lobed - Quercus roubar
Palmate - Aesculus hippocastanum
Pinnate - Fraxinus excelsior

Question 14

Leaf Adaptions

Answer 14

Tendril
Spines
Water Storage
Carnivorous
Perennation

Question 15

Leaf Adaptions - Tendril

Answer 15

Climbing by Tendril, modified leaflet.
Support and height to increase availability of Light, Air and chance of Pollination.

Pisum sativum (Garden Pea)

Question 16

Leaf Adaptions - Twining Petioles

Answer 16

Clematis spp.

Question 17

Leaf Adaptions - Spines

Answer 17

Modified leaves for protection from predators.

Berberis thunbergii

Question 18

Leaf Adaptions - Water Storage

Answer 18

Succulent fleshy leaves for water storage.

Hylotelephium ‘Herbstfreud’

Question 19

Leaf Adaptions - Carnivorous

Answer 19

Venus Fly Trap, to ensure nutrients in short supply for the plants situation.

Dionaea muscipula

Question 20

Leaf Adaptions - Perennation

Answer 20

Bulb, modified scale leaves. Used for food and water storage for next seasons growth.

Narcissus pseudonarcissus