35 Plant Structure, Growth and Development

Question 1

What is a tissue?

Answer 1

A group of cells consisting of one or more type of cell.

Question 2

What are the main systems of a plant?

Answer 2

The shoot system and the root system.

Question 3

What is the major terminology that describes the shoot system?

Answer 3

The main shoot is called the stem. It has ‘vegetative shoots’ that grow of. They are joined to the stem by ’nodes’. The region between the nodes is called the ‘internode’

At the top of the stem and at the end of each vegetative shoot is an ‘apical bud’. (end of vegetative shoot may be leaf) Along the stem there may be ‘auxillary buds’

Besides ‘vegetative shoots’, ‘reproductive shoots’ also branch of from the stem and terminate in flowers.

Question 4

What are the two most basic patterns of root systems?

Answer 4

’Taproot systems’ and ‘’fibrous root systems’

Question 5

Describe a ’taproot system’?

Answer 5

A single vertical ’tap root’ is a thick root that is an extension of the stem.

Along its length ‘lateral (branch roots)’ branch of it more-or-less horizontally.

Question 6

Describe a ‘fibrous root system’

Answer 6

A mat of thin roots spread out under the soil.

Question 7

How do ’taproots’ and ‘fibrous roots systems’ differ in their adaption to specific climates?

Answer 7

Fibrous roots systems do not usually penetrated as far and are thus best adapted to shallow soils or regions where rainfall is light do does not moisten the soil far below ground level.

Tap roots often anchor the plant better. The fibrous roots are could at holding the topsoil in place hence why grasses prevent erosion.

Question 8

In what plants are taproots typically seen?

Answer 8

Most eudicots and gymnosperms

Question 9

In what plants are fibrous roots systems typically seen?

Answer 9

Monocots such as grasses.

Question 10

What adaptation is found on many roots to increase the rate at which they can absorb nutrients?

Answer 10

Fine projections called ‘root hairs’

Question 11

What are some specific forms of roots with evolutionary advantages?

Answer 11

Prop roots, storage roots, ’Strangling aerial roots’ buttress roots and pneumatophores

Question 12

What are prop roots?

Answer 12

Roots that extend from the lower trunk of a tree.

This helps support the tree such as the Hala trees that live in unstable sand soils in the South Pacific.

Question 13

What are storage roots?

Answer 13

Roots that can store water and nutrients underground, often by swelling.

These include potatoes.

Question 14

What are ’Strangling’ aerial roots?

Answer 14

The seeds of these species germinate in the branches of tall trees of other species and send many aerial roots to the ground. These snakelike roots gradually wrap around the host tree and kill it by blocking its light

Question 15

What are buttress roots?

Answer 15

Like prop roots they extend from the trunk although buttress roots often start lower.

Unlike prop roots which a are normal sticks the area under the ‘buttress root’ is filled so that they are ◢

Question 16

What are ‘penumatophores’?

Answer 16

Roots that stick out of the ground i.e. the ones mangroves have.

They are important for roots to obtain oxygen which is lacking the thick, waterlogged roots.

Question 17

What types of roots do mangroves have?

Answer 17

‘Pneumatophores’

Question 18

What does ’node’ refer to on a plant?

Answer 18

Where the leaf joins the stem

Question 19

What does ‘internode’ refer to on a platns?

Answer 19

The stem segment between nodes.

Question 20

What are the shoots that branch of the plant called?

Answer 20

Lateral shoots or more often ‘branches’

Question 21

What is a bud composed of?

Answer 21

Developing leaves and a compact series of nodes and internodes

Question 22

What is found at the top of the stem and of each lateral shoot?

Answer 22

Apical buds aka ’terminal buds’

Question 23

What are buds on the sides of the stem called?

Answer 23

Auxillary buds.

Question 24

What determines which bud develops?

Answer 24

Generally speaking the growth is concentrated at the ‘apical bud’ as it exerts ‘apical dominance’ that suppresses the growth of the auxiliary buds.

If the apical bud becomes shaded its will lessen this suppression. This allows the auxiliary buds to develop into a ’lateral shoot’ (branch) to allow the plant to get light.

Question 25

What are the basic structures plants have to perform asexual reproduction?

Answer 25

Rhizomes, bulbs, stolons and tubers.

Question 26

What asexual reproduction structure is a root?

Answer 26

None: they are all technically stems event if they are underground.

Question 27

What are ‘rhizomes’?

Answer 27

An underground asexual structure that consist of a shoot that grows just under the soil surface.

Along the rhizomes are auxiliary buds that can develop into vertical stems and thus new plants.

Question 28

What are ‘bulbs’?

Answer 28

Vertical underground shoots that consist of the enlarged bases of leaves that store food.

The individual leaves, called ’storage leaves’ explain the many layers of an onion: each layer is a leaf.

Question 29

What are stolons?

Answer 29

Horizontal shoots that grow along the surface.

They allow asexual reproduction as ‘plant lets’ form at nodes along each ‘runner’ (stolon)

Question 30

What are tubers?

Answer 30

Enlarged ends of rhizomes or stolons that are specialised for storing food in the form of starch.

Question 31

What is the basic structure of a leaf?

Answer 31

It is connected to a ‘node’ by a ‘petiole’.

The actual leaf may con of a ‘main rib’ (eudicot only?) and a series of smaller veins to transport nutrients to and from the leaf cells.

The actual leaf blade is called the lamina?

Question 32

How does leaf structure differs between plant species?

Answer 32

In Monocots there are typically veins that pun in parallel from the petiole. for example the flax leaves

In Eudicot leaves there is typically a ’net like web’ of veins.

Question 33

What are the fundamental ways in which leaves are structured ?

Answer 33

Simple leaf, compound leaf and ‘doubly compound leaaves’

Question 34

What are ’simple leaves’?

Answer 34

When the leaf has a simple undivided lamina and is to only one that extends from the petiole.

Question 35

What compound leaves?

Answer 35

In a compound leaf, the blade consists of multiple leaflets. A leaflet has no axillary bud at its base.

Each leaflet connects to the petiole not the stem.

Question 36

What are double compound leaves?

Answer 36

Each leaflet is divided into smaller leaflets.

Therefore ‘compound leaves’ branch of from the petiole.

Question 37

What are some advantages to compound leaves?

Answer 37

Since each leaflet is smaller than a normal leaf this prevents it from catching in the wind and falling off easily.

Pathogens might only infect one small leaflet, not the entire leaf.

Question 38

What are some special adaptions of leaves?

Answer 38

Tendrils, Spines, Storage leaves, reproductive leaves and Bracts.

Question 39

What are tendrils?

Answer 39

Modified leaves that that cling onto neighbouring plants etc. and thus support the plant.

(note that tendrils are often leaves but can be stems in some species)

Question 40

What are spines?

Answer 40

The spines of cacti are actually leaves; photosynthesis is carried out by the fleshy green stems which constitute to main body of the cactus.

Question 41

What are storage leaves?

Answer 41

Swollen leaves that many succulents have to store water

Question 42

What are reproductive leaves?

Answer 42

Leaves that aid in asexual reproduction.

For example Kalanchoë daigremontiana, produce adventitious plantlets, which fall off the leaf and take root in the soil.

Question 43

What does ‘adventitious’ refer to?

Answer 43

A plant organ that grows in an unusual location, such as roots arising from stems or leaves.

Question 44

What is the word that means growing from an unusual place i.e. roots from the stem?

Answer 44

‘Adventitious’

Question 45

What are the basic types of plant tissue?

Answer 45

Dermal tissue, ground tissue and vascular tissue.

Question 46

What is the ‘dermal tissue’?

Answer 46

The outer layer of the plant that acts as its protective coating.

Question 47

What are some examples of dermal tissue?

Answer 47

In nonwoody plants there is tissue called the epidermis (tightly packed cells). In woody plants, protective tissues called periderm replace the epidermis in older regions of stems and roots.

In leaves and most stems, the cuticle (waxy coating on epidermis surface) helps prevent water loss.

Question 48

What is an example of a specialised structure pro ducted by some plants on the dermal tissue?

Answer 48

Trichomes

Question 49

What are trichomes and what advantage do they offer?

Answer 49

Hairlike outgrowths of the shoot epidermis.

In some desert species, they reduce water loss and reflect excess light,

However their primary function is to provide defense against insects by forming a barrier or by secreting sticky fluids or toxic compounds.

For instance, the trichomes on aromatic leaves such as mint secrete oils that protect the plants from herbivores and disease.

Question 50

What is the purpose of the vascular tissue system?

Answer 50

To carry nutrients throughout the plant.

Question 51

What are the main components of the vascular tissue system?

Answer 51

Xylem and Phloem

Question 52

What is the vascular system of a root or stem collectively called?

Answer 52

Its ’stele’

Question 53

What does ’stele’ refer to?

Answer 53

The collective vascular system of a root or stem.

Question 54

How does the arrangement of the ’stele’ vary between plants and regions?

Answer 54

In angiosperms the root stele is a solid central vascular cylinder of xylem and phloem. T

he stele of stems and leaves consists of vascular bundles, separate strands containing xylem and phloem.

Question 55

What does the ground tissue system consist of?

Answer 55

Pretty much anything that isn’t vascular or dermal.

It is divided into ‘pith’ and ‘cortex’

Question 56

What is the difference between ‘pith’ and ‘cortex’ in the ground tissue system?

Answer 56

Ground tissue that is internal to the vascular tissue is known as pith, and ground tissue that is external to the vascular tissue is called cortex.

Question 57

What is the function of the ground tissue?

Answer 57

It is not just a filler and thus is involved in storage, photosynthesis and support of the plant.

Question 58

What are the basic types of plant cells?

Answer 58

Parenchyma, Collenchyma and Sclerenchyma.

Question 59

What is the structure of parenchyma cells?

Answer 59

They have thin and flexible primary cell walls with most lacking secondary cell walls.

They typically have a large central vacuole.

Most parenchyma cells retain the ability to divide and differentiate into different plant cell types i.e. for wound repair

Question 60

What functions do parenchyma cells perform?

Answer 60

They perform most of the metabolic functions of the plant, synthesizing and storing various organic products

For example photosynthesis occurs within the chloroplasts of parenchyma cells. Some parenchyma cells in stems and roots have colourless plastids that store starch.

Therefore parenchyma a cells are typically alive when mature

Question 61

What is the fleshy tissue of most fruits mad up of?

Answer 61

Parenchyma cells

Question 62

What is the structure of collenchyma cells?

Answer 62

They are elongated cells that are often found in stands. They have thicker primary cells walls than parenchyma cells but the walls are unevenly thickened.

Question 63

What is the purpose of collenchyma cells?

Answer 63

Young stems and petioles have strands of collenchyma cells below their epidermis. to support theses structures. They are flexible so don’t restrain growth.

At maturity, these cells are living and flexible, elongating with the stems and leaves they support

Question 64

What is the structure of sclerenchyma cells?

Answer 64

They are more rigid than collenchyma as they have thick secondary cell walls with large amounts of lignin.

Sclerenchyma cells are divided into two types: sclereids and fibres

Question 65

In what organisms are sclerenchyma cells found?

Answer 65

All vascular plants but no bryophytes.

Question 66

What is the function of sclerenchyma cells?

Answer 66

They can not elongate and thus support regions of the plant that have stopped growing. For example they make up a large component of wood.

Since their main function is to support the cell most produce thick secondary cell walls and then die as they mature, leaving behind a skeleton.

Question 67

What are the basic types of sclerenchyma cell?

Answer 67

Sclereids and fibres.

Question 68

How do ’sclereids’ and ‘fibres differ’

Answer 68

Both are forms of sclerenchyma and thus have thick lignified secondary cell walls as they function in support.

Sclereids, are boxier than fibers and irregular in shape, have very thick, lignified secondary walls.

Fibers, are usually grouped in strands and are long, slender, and tapered.

Question 69

Where are sclereids found?

Answer 69

They are what make nutshells and seed coats hard and give pears their gritty texture.

Question 70

Where are fibres (sclerenchyma) found?

Answer 70

They are uses for making ropes. Flax fibres are used for weaving into linen.

Question 71

What is xylem composed of?

Answer 71

Two different types of ‘water-conducting cells’: tracheids and vessel elements.

Question 72

In what plants are tracheids found in xylem?

Answer 72

Almost all vascular plants

Question 73

In what plants are vessel elements found in xylem?

Answer 73

Most angiosperms, a few gymnosperms and some seedless vascular plants.

Question 74

What is the structure of tracheids?

Answer 74

They are long, thin cells with tapered ends.

Water moves from cell to cell through ‘pits’ which are regions where the the secondary cell wall is missing and thus water has to pass only through the primary cell wall.

Question 75

What is the structure of vessel elements?

Answer 75

Vessel elements are generally wider, shorter, thinner walled, and less tapered than the tracheids.

They are aligned end to end in a stack, forming long micropipes known as vessels.

The end walls of vessel elements have ‘perforation plates’ (the walls have lots of holes) so enable water to flow freely through the vessels.

Question 76

What prevents the tracheids and vessel elements from collapsing?

Answer 76

They are hardened with lignin which not only prevents them from collapsing but also supports the platen.

Question 77

What type of structure are the stalks of celery?

Answer 77

Petioles as they support the leaves.

Question 78

What makes up the ’strings’ of celery?

Answer 78

Collenchyma cells.

Question 79

Besides tracheids and ‘xylem vessels’, what structures are found in xylem?

Answer 79

Xylem fibres and Xylem parenchyma.

Question 80

What are xylem vessels also known as?

Answer 80

Xylem Tracheae

Question 81

What are xylem fibres?

Answer 81

Dead sclerenchyma fibres that found between the vessels and the tracheids that provide mechanical support.

Question 82

What are xylem parenchyma?

Answer 82

This is the only living component in the xylem tissue and consists of parenchyma cells.

They store reserves of food.

Question 83

What is xylem divided into?

Answer 83

Primary xylem and secondary xylem

Primary xylem is further divided into protoxylem and metaxylem

Question 84

How do protoxylem and metaxylem differ?

Answer 84

When xylem first forms it starts as protoxylem then develops into metaxylem and eventually secondary xylem.

Protoxylem has a narrower lumen. Protoxylem undergoes ‘annular and spiral thickening’ whereas metaxylem undergoes ’sclariform, reticulate and pitted thickening’

Question 85

What is phloem composed of?

Answer 85

Two types of ‘water conducting cells:’ Sieve tubes or sieve cells

Question 86

How does the structure of phloem differ between plants?

Answer 86

Seedless vascular plants and gymnosperms have phloem with ’sieve cells’

Angiosperms have ’sieve tubes’ which are composed of chains of cels called ’sieve tubes elements’ (aka sieve tube members)

Question 87

What is the detailed structure of phloem in angiosperms?

Answer 87

The phloem consists of stacks of individual cells called ’sieve tube elements.’ The sieve tube elements are alive but have no nucleus, ribosomes, distinct vacuole or cytoskeletal elements. The absence of these structures allows food to move more easily

Where the sieve tube elements join in the stack is a ’sieve plate’ with pores to allow food to move between the sieve-tube elements.

The sieve tube elements are surrounded by ‘companion cells’ which are connected to the sieve tube elements by plasmodesmata. This allows proteins synthesised in the companion cell to be transported to the nucleus-less sieve tube element.

In some plants the companion cells in leaves also help load sugars into the sieve-tube elements.

Question 88

A sieve tube element has no nucleus or ribosomes but is still alive. How is this possible?

Answer 88

The companion cell supplies it with proteins using plasmodesmata between the sieve-tube element and the companion cell.

Question 89

Plants growth throughout their lives. What is this called?

Answer 89

Indeterminate growth.

Question 90

Animals generally stop growing when they reach certain size. What is this called?

Answer 90

Determinate growth i.e. to a ‘determined’ size

Question 91

What allows plants to keep on growing?

Answer 91

They leave undifferentiated regions i.e. ‘meristems’

Question 92

What meristems are found in plants and what form of growth are they involved in?

Answer 92

Apical meristems are found at the top of stems etc. and thus allow primary growth.

Lateral meristems are composed of ‘cork cambium’ dab ‘vascular cambium’ and thus allow secondary growth.

Question 93

What are the basic types of growth a plant undergoes? What is the result of each?

Answer 93

In primary growth the plant gets taller and in secondary growth its structures i.e. the stems get thicker.

Question 94

How can cells undergoing mitosis be identified?

Answer 94

By staining for ‘cyclin’, a key protein in cell division

Question 95

What are the types of cambium seen in stems and what does each form?

Answer 95

Vascular cambium forms secondary xylem and secondary phloem

Cork cambium adds secondary dermal tissue.

Question 96

Rephrase the statement ’the cells of the cambium become specialised cells’ using correct terminology?

Answer 96

The cells of the cambium are ‘initials’ (aka stem cells, even in plants) this means that they can become more specialised cell.

These ‘initials’ then differentiate in to ‘derivatives’ which are more specialised cells i.e. secondary xylem

Question 97

What are ‘leaf scars’?

Answer 97

Scars left on the plant from petioles that have detached i.e. when trees lose their leaves

Question 98

What is the formal term for when tress lose their leaves?

Answer 98

Defoliation

Question 99

How can plants be grouped based on how long their life cycle is?

Answer 99

‘Annuals’ complete their lifecycle i.e. germinate → flower → die within a year or less

‘Biennials’ complete their lifecycle through years.

‘Perennials’ live many years

Question 100

What are some examples of ‘annuals’?

Answer 100

Many wildflowers, legumes, wheat and rice

Question 101

What are some examples of ‘biennials’?

Answer 101

Turnips

Question 102

What are some examples of ‘perennials’?

Answer 102

Trees, shrubs and some grasses.

Question 103

What protects the root as it travels through the soil?

Answer 103

The root cap which is found on the tip of the apical meristem of the root.

Question 104

What is the purpose of the root cap?

Answer 104

To protect the root as it pushes through the soil and to secrete a polysaccharide slime to lubricate the soil.

Question 105

What are the stages of primary growth?

Answer 105

Division, elongation, differentiation.

Question 106

The stages of primary growth do not occur at once. What is the consequence of this in terms of where each form of growth occurs.

Answer 106

The newly formed cells are undergoing the first stage: division and thus form the ‘zone of cell division’.

Eventually as new cells are formed these original cells will begin elongation and hence form the ‘zone of elongation’.

Eventually cells in the ‘zone of differentiation’ differentiate into specific cells.

Question 107

What occurs during the ‘division’ stage of primary growth?

Answer 107

Cells of the apical meristem become generic root cells.

The apical meristem cells undergo mitosis to form new cells while retaining a constant supply of undifferentiated cells.

Question 108

What occurs during the ‘elongation’ stage of primary growth?

Answer 108

The cells take in water and expand to up-to 10 times their size.

It is this expansion that forces the root deeper into the soil.

Question 109

What happens during differentiation?

Answer 109

The generic cells differentiate into specific cells.

This is, for example, where root hairs are formed

Question 110

When in a root are root hairs found?

Answer 110

In its entirety excluding the zone of elongation and the zone of division because root hairs only form after differentiation.

Question 111

What happens during differentiation?

Answer 111

The generic cells differentiate into specific cells.

This is, for example, where root hairs are formed

Question 112

What aid the basic cross-sectional structure of a stem that has undergone secondary growth?

Answer 112

• At the centre is pith
• Then the primary xylem in individual vascular bundles arranged like a ferris wheel.
• Then a complete ring of secondary xylem
• A complete ring of vascular cambium
• A complete ring of secondary phloem
• A few individual bundles of primary phloem arranged like a ferris wheel
• The cortex
• The cork cambium
• The outermost layer is the periderm which is formed by the cork cambium.

Question 113

What aid the basic cross-sectional structure of a stem that has only undone primary growth?

Answer 113

In order from centre to outside:

• Pith at the centre
• A ring of individual vascular bundles with primary xylem on the inside and primary phloem on the outside
• Cortex to the outside of the vascular bundles.
• Epidermis surrounding the stem

Question 114

What does cork and bark develop from?

Answer 114

Periderm which is in turn produced by the cork cambium

Question 115

What does the cork cambium form?

Answer 115

Periderm which later becomes cork and bark

Question 116

What does cork and bark develop from?

Answer 116

Periderm which is in turn produced by the cork cambium

Question 117

What is the basic cross-sectional structure of a root?

Answer 117

It has an outer epidermis layer. Then cortex.

Next is a thin ring of vascular tissue called the ’endodermis’ which is a form of ground tissue.

In side the endodermis is another ring of cells, this time vascular, called the ‘pericycle’.

In side the pericycle is the vascular cylinder, which differs between eudicots and monocots

Question 118

What is the structure of the vascular cylinder in eudicots?

Answer 118

Inside the pericycle is a star shaped i.e. * collection of xylem.

Surrounding this star is phloem cells.

Question 119

What is the structure of the vascular cylinder in monocots?

Answer 119

Inside the pericycle is a thick ring of phloem cells.

Inside this ring xylem cells are arranged in distinct vascular bundles like a ferris wheel.

At the core of the root is a core of parenchyma cells.

Question 120

What type of tissue is cortex?

Answer 120

Ground

Question 121

What type of tissue is endodermis?

Answer 121

Ground (not dermal)

Question 122

What type of tissue is the core of parenchyma seen in monocot roots?

Answer 122

Vascular

Question 123

What type of tissue is the pericycle?

Answer 123

Vascular

Question 124

What type of tissue are the root hairs?

Answer 124

Dermal.

Question 125

What type of tissue is Pith?

Answer 125

Ground.

Question 126

What is the function of ground tissue in roots?

Answer 126

To store carbohydrates and absorb water and minerals from the soil.

Question 127

What type of tissue is Pith?

Answer 127

Ground.

Question 128

What is the function of ground tissue in roots?

Answer 128

To store carbohydrates and absorb water and minerals from the soil.

Question 129

What do lateral roots form?

Answer 129

A lateral root originates form the pericycle (outermost layer of the vascular cylinder) It continues to grow through the cortex of the main root.

Eventually it grows out through the dermis of the root and thus a ‘lateral root’ appears on the side.

Question 130

What is tissue in the root forms a boundary between the vascular and ground tissue?

Answer 130

The endodermis

Question 131

How are leaves formed?

Answer 131

They develop from ‘leaf primordial’ which are finger-like projections along the sides of the apical meristem.

Question 132

Where specifically in the stem does primary growth occur?

Answer 132

In the ‘internode’ regions between leaves. Therefore the leaf ’nodes’ become farther apart as primary growth occurs.

Question 133

How does ‘branching occur’?

Answer 133

‘Axillary’ buds on the side of the stem begin to develop.

Question 134

Is branching a form of secondary growth, primary growth or neither?

Answer 134

Primary growth.

Question 135

Which buds are more likely to be inhibited: ones closer to the apical buds or ones further?

Answer 135

The ones closer to the active apical buds will likely be more strongly inhibited.

Question 136

What adaption do some plants have to allow them to continue growing even if their tops are cut off?

Answer 136

Some monocots, particularly, grasses have meristems called ‘intercalary meristems’ at the base of the stems and leaves.

Therefore if the end of the leaf is chopped off i.e. through herbivory the grass etc. can continue growing.

Question 137

How do lateral shoots develop?

Answer 137

They arise form from the epidermis tissue.

Question 138

What is the advantage of lateral shoots developing from the epidermis as opposed to developing from the vascular cylinder as in roots?

Answer 138

The method in roots disrupts the vascular cylinder and thus does not allow nutrients to pass. To mitigate this many roots fork like -

Question 139

What is a the typical structure of a monocot stem in cross section?

Answer 139

It has a thin layer of epidermis with an interior filled with ‘ground tissue’

Inside this ground tissue are scattered individual vascular bundles.

Question 140

What type of tissue are sclerenchyma?

Answer 140

Vascular.

Question 141

What type of cells are in the ground tissue of roots?

Answer 141

Mainly parenchyma. However, collenchyma cells just beneath the epidermis strengthen many stems.

Sclerenchyma cells (especially ‘fibre cells’) also provide support in those parts of the stems that are no longer elongating.

Question 142

What are ‘fibre cells’?

Answer 142

A form of sclerenchyma.

Question 143

What is the cross sectional structure of a eudicot root?

Answer 143

Form outside to in:

They have an epidermis then a layer of ‘cortex’ Arranged in a ring like a ferris wheel are multiple vascular bundles.

Further inside is central layer of ‘pith’ in the gaps between the vascular bundles is “ground tissue connecting pith to cortex”

Each vascular bundle is like a stack (| | | | ) of tissues. The tissue closes to the epidermis is a layer of ’sclerenchyma (fibre cells)’ Next is a layer of phloem, then cambium then xylem.

Question 144

In roots, what is on the outside: xylem or phloem?

Answer 144

In monocot roots the xylem is on the inside.

In eudicot roots the xylem is also on the inside forming star shape. This star is surrounded by phloem.

Question 145

In roots, what is on the outside: xylem or phloem?

Answer 145

Phloem

Question 146

In leaves, what is on the outside?

Answer 146

In leves the xylem is at the top (towards the palisade cells.)

Question 147

From top to bottom, what are the tissues of the leaf?

Answer 147

Cuticle + (stoma)
Upper epidermis + (stoma)
Palisade mesophyll + sclerenchyma fibres
Vascular bundle + (spongy mesophyll)
Spongy mesophyll + sclerenchyma fibres
Lower epidermis + (guard cells, stoma)

Question 148

What is the structure of the vascular bundle of a leaf?

Answer 148

It has an outer ring formed from ‘bundle sheath cells’ In side this is the actual vein.

The upper layer of the vein is ht xylem and the lower level is the phloem.

Question 149

What type of tissue is the upper epidermis in the leaf?

Answer 149

Dermal

Question 150

What type of tissue is the palisade mesophyll in the leaf?

Answer 150

Ground

Question 151

What type of tissue is the spongy mesophyll in the leaf?

Answer 151

Ground

Question 152

What type of tissue is the lower epidermis in the leaf?

Answer 152

Dermal

Question 153

What type of tissue is the vein in the leaf?

Answer 153

Vascular (note that the vein is just the xylem and phloem - it does not include the surrounding bundle-sheat cells)

Question 154

What type of tissue are the bundle sheath cells in the leaf?

Answer 154

Ground

Question 155

What type of tissue is the xylem in the leaf?

Answer 155

Vascular

Question 156

What type of tissue is the phloem in the leaf?

Answer 156

Vascular

Question 157

What type of tissue is the guard cells in the leaf?

Answer 157

Dermal

Question 158

Where are the sclerenchyma fibres found in a leaf and what function do they play?

Answer 158

They are found connecting the upper epidermis and lower epidermis to the vascular bundle. In this way they hold the vascular bundle in place whilst also providing support for the entire leaf.

Question 159

What is mesophyll primarily composed of?

Answer 159

Parenchyma cells.

Question 160

What type of cells constitute the bundle sheath cells of the leaf vein?

Answer 160

Typically parenchyma.

Question 161

Where does the growth of secondary growth occur?

Answer 161

In the ‘lateral meristems’.

Question 162

What species undergo secondary growth?

Answer 162

All gymnosperms, most eudicots but very few monocots

Question 163

Note:

Answer 163

Primary growth and secondary growth occur simultaneously,

Question 164

What provides the undifferentiated cells needed for secondary growth?

Answer 164

Vascular cambium

Question 165

What are the cells in the vascular cambium a type of?

Answer 165

Conceptually: Meristematic cells, Physically: parenchyma cells.

Question 166

What happens during secondary growth?

Answer 166

The stem thickens as the vascular cambium forms secondary xylem to the inside and secondary phloem to the outside.

Some initials of the vascular cambium give rise to vascular rays.

As secondary growth continues to increase the diameter of the vascular cambium the secondary phloem outside it ruptures as it doesn’t increase in diameter.

A second lateral meristem, the cork cambium, develops from parenchyma cells in the cortex. The cork cambium produces cork cells, which replace the epidermis.

Each cork cambium and the tissues it produces form a layer of periderm which is part of the bark.

Question 167

What does ‘bark include’?

Answer 167

All the layers exterior to the vascular cambium. This includes the secondary phloem, cork cambium an the periderm produced by the cork cambium.

Question 168

Besides secondary phloem and xylem, what does the vascular cambium produce?

Answer 168

‘Vascular rays’

Question 169

What are vascular rays?

Answer 169

Radial fibres of mostly parenchyma cells found between secondary xylem and secondary phloem.

These ‘vascular rays’ move water and nutrients between the secondary xylem and phloem, store carbohydrates and aid in wound repair.

Question 170

What accounts for the strength of wood?

Answer 170

It has secondary xylem with highly lignified xylem cells.

Question 171

What causes secondary tree rings?

Answer 171

In temperate regions, wood that develops early in the spring, known as early (or spring) wood consists of secondary xylem cells with larger diameters and thin cell walls to maximised delivery of water to new leaves.

Wood produced during the rest of the growing season is called late (or summer) wood. It is composed of thick-walled cells that do not transport as much water but provide more support.

In temperate regions, the vascular cambium becomes inactive during winter.

The larger thin walled cells are lighter in colour than the small cells. Therefore these seasonal variation leads to an alternating pattern of light and dark bands and thus tree rings.

Question 172

When analysing tree rings, what are some important factors to consider?

Answer 172

• There is one dark band per year
• The newest ring will be the one on the outside i..e just internal to the vascular cambium. Therefore the oldest rings will be at the centre
• A thicker ring indicates better growth i.e. more available nutrients/photosynthesis performed.

Question 173

Why is the production of bark important?

Answer 173

To replace the epidermis which cracks and falls off as the stem increases in diameter.

Question 174

Does cork form in roots?

Answer 174

Yes.

Question 175

What happens to the cork cambium as the stem/root expands?

Answer 175

It splits and cracks as the stem diameter increases and thus loses its meristematic ability.

Therefore new cork cambiums must be produced as the old ones become cork.

Question 176

How does the cork cambium produce bark?

Answer 176

It differentiates to produce a thin layer of parenchyma cells to its interior called the ‘phellloderm’

To the exterior it forms cork cells. As cork cells mature, they deposit a waxy, hydrophobic material called ‘suberin’ in their walls and then die. This makes the ‘cork tissue’ waterproof

Question 177

Why is the formation of cork tissue important?

Answer 177

It protects the stem or root from water loss, physical damage, and pathogens

Question 178

What is the material formed by cork cells to make them waterproof?

Answer 178

Suberin

Question 179

The cork tissue is largely waterproof: what are the consequences of this and how are they mitigated?

Answer 179

Heavily wooded roots can’t perform water absorption and thus are primarily used for support and to extend the root system deeper.

This would block gases form entering the stem/root and thus would suffocate living cells i.e phloem inside. To mitigate this small raised areas called lenticels are places along the woody stem/root in which there are greater spaces between the cork cells and thus gases can permeate. These lenticel often appear as horizontal slits.

Question 180

What are ‘lenticels’?

Answer 180

Regions of the stem/root with extra spaces between the cork cells to allow living cells i..e phloem in the woody stem or root to perform gas exchange.

Question 181

What does ’development’ refer to?

Answer 181

A specific series of changes in which cells form tissue, organs and organisms.

Question 182

What are the basic processes that occur during development?

Answer 182

‘Growth’, ‘morphogenesis’ and ‘differentiation’

Question 183

What is ‘growth’ in terms of development?

Answer 183

A long-term increase in size

Question 184

What is ‘morphogenesis’ in terms of development?

Answer 184

The process which gives a tissue, organ or organism its shape. It also involves determining the position of cell types.

Question 185

What are B cells classed as?

Answer 185

Lymphocytes

Question 186

What are T cells classed as?

Answer 186

Lymphocytes

Question 187

What does ‘lymphocyte’ include?

Answer 187

B cells and T cells.

Question 188

What is ‘differentiation’ in terms of development?

Answer 188

The process in which cells of one type develop into more specialised cells.

Question 189

What causes differentiation to occur?

Answer 189

The new cell will have the same genes but changes in their expression leads to cellular differentiation.

Question 190

What are the basic mechanisms in which plant growth occurs?

Answer 190

By ‘cell division’ and ‘cell expansion’

Question 191

How do plant cells grow by expansion?

Answer 191

They intake water causing them to swell and thus elongated.

Question 192

What is the ‘pre-prophase band’

Answer 192

Microtubules in the cytoplasm become concentrated into a ring called the preprophase band.

The band disappears before metaphase but predicts the future plane of cell division.

Question 193

What is an important factor in growth by cell division?

Answer 193

It has a determined ‘plane’ which directs in which direction the cell plate will form and thus in which direction growth will occur.

Question 194

What is the typical ‘plane’ of cell division?

Answer 194

The one which cuts through the shortest distance i.e. if it was a rectangle like [] it would be horizontal.

Question 195

What does ’plane’ refer to?

Answer 195

The direction in which the cell plate forms and thus the direction of growth by cell division.

Question 196

What is ’suberin’?

Answer 196

A chemical released to make bark waterproof.

Question 197

What can lead to unusual planes of division during cell growth by division?

Answer 197

A mutant form called ’tangled-1’

Question 198

What happens to those with ’tangled-1’

Answer 198

In plants of this mutates form plane of cell division is random and thus instead of forming a grid of cells and random “tangled mess” appears.

The leaves grow slower but actually end up looking normal to the naked eye.

Question 199

What can cell division be divided into?

Answer 199

’Symmetric division’ and ‘asymmetric division’

Question 200

How do symmetric division and asymmetric division differ?

Answer 200

In symmetric division the cell plate forms halfway along the cells and thus after cytokinesis two cells with an equal amount of cytoplasm form and thus are of equal size.

In asymmetric division the cytoplasm is not evenly shared and thus a big cell and a small cell results.

(note that both daughter cells have nuclei etc.)

Question 201

What is an example of where ‘asymmetrical cell division’ is used?

Answer 201

The formation of guard cells.

Question 202

How are guard cells formed?

Answer 202

An epidermal cell divides asymmetrically, forming a large cell that remains an unspecialized epidermal cell and a small cell that becomes the guard cell “mother cell.”

Guard cells form when this small mother cell divides in a plane perpendicular to the first cell division.

Question 203

What does ‘fate’ refer to in terms of cells?

Answer 203

What the cell is destined to develop into.

Question 204

What is it called when organisms have structural or chemical differences at each end?

Answer 204

Polarity

Question 205

What does ’polarity’ refer to?

Answer 205

The condition of having structural or chemical differences at opposite ends of an organism.

Question 206

How is directionality initiated in growth by expansion?

Answer 206

Cellulose microfibrils grow in bands around the cube shaped cell.

These rings do not expand. Therefore the cell can only grow up.

Question 207

What are the basic processes which lead to specialised structures in plants called?

Answer 207

Morphogenesis and Pattern Formation

Question 208

How does Morphogenesis differ from Pattern Formation?

Answer 208

During morphogenesis, cells acquire different identities in an ordered spatial arrangement i.e. dermal tissue forms on the exterior, and vascular tissue in the interior

The development of specific structures in specific locations is called pattern formation.

Question 209

What is the basic concept which allows ‘pattern formation’?

Answer 209

Cell fate in which a basic cell is destined to be a specific one.

Question 210

What are the leading hypotheses which describe how cell fate leads to pattern formation?

Answer 210

The ‘lineage-based mechanisms’ and ‘position-based mechanisms’ hypothesises.

Question 211

What is the ‘lineage-based mechanism’ of pattern formation?

Answer 211

The idea that cell fate is determined early in development and that cells pass on this destiny to their progeny.

This leads to ideas such as that cells at the top of the embryo will develop into ____ and those at the bottom will eventually becomes cells that develop into ___.

Question 212

What is the ‘position-based mechanism’ of pattern formation?

Answer 212

The idea that cell fate is not determined based on where the originate but where they are currently located.

This is determined by chemical signals that are released form the neighbouring cells.

Therefore theoretically speaking if a random undifferentiated cell was placed in a vein it would theoretically become a phloem/xylem cell.

This also explains how cells formed by mitosis after injury become the correct type of cell.

Question 213

How does cell differentiation occur conceptually?

Answer 213

With ‘differential gene expression’ in which certain genes are expressed more than others leading to different proteins and thus different features.

Question 214

What is the ‘GALBRA-2’ gene involved in?

Answer 214

Controlling the distribution of root hairs on a root.

Question 215

How can plant growth be described in terms of how the plant ages?

Answer 215

It ages in ‘phases’ which are specific stages with specific patterns of growth i.e. large leaves fro one phase, bug buds for the next.

Basically phases are just stages in the lifecycle i.e. child, adolescent and adult etc. in humans.

The transition between phases is called ‘phase change’ and is analogous to puberty

Question 216

What does ’phase’ refer to?

Answer 216

A specific stage in plant development i.e “adult” or “child” if in human.

Question 217

What does ’phase change’ refer to?

Answer 217

The transition between phases of plant growth, analogous to puberty.