Plant development I - plants are composed of repeated structural units

Question 1

plants are composed of…

Answer 1

repeated structural units

Question 2

… coordinate plant development

Answer 2

plant hormones

Question 3

Describe the roots

Answer 3

• highly explorative
• explore large areas and volumes of soil
• induce immobility
• allow social acquisition of nutrients

Question 4

What are the constraints of immobility

Answer 4

exposed to aggregation and inclemency of weather and elements

Question 5

Describe plant organs

Answer 5

can grow above- (shoot system) and under-ground (root system)

Question 6

List some plant organs

Answer 6

• reproductive shoot (flower)
• modified leaves (petals)
• stamens and carpels
• bud
• leaf
• taproot
• lateral roots

Question 7

List 3 directions of plant growth

Answer 7

• apical
• branching
• radial

Question 8

Give some examples of apical growth

Answer 8

• shoots
• taproots

Question 9

Give some examples of branching growths

Answer 9

• … branches
• lateral roots

Question 10

Give some examples of radial growth

Answer 10

• tubers

Question 11

List three different plant tissue systems

Answer 11

• epidermal system
• ground tissue system
• vascular tissue system

Question 12

Describe permanent plant tissues

Answer 12

can be simple, complex or secretory

Question 13

Describe the simple permanent plant tissues

Answer 13

• parenchyma
• schlerenchyma
• collenchyma
• epidermis

Question 14

Describe plant organs

Answer 14

• composed of different tissue systems, each characterised by one or more cell types with characteristics that provide specific functions

Question 15

How can plant tissues be divided?

Answer 15

meristems and the permanent tissues

Question 16

Describe the SAM

Answer 16

• contained in the terminal bud
• responsible for the production of shoot-organs

Question 17

SAM

Answer 17

shoot apical meristem

Question 18

Describe the cambia

Answer 18

• vascular cambium and cork cambium
• meristematic tissues that enable increase in thickness of stems and roots

Question 19

Describe the RAM

Answer 19

produces new cells at the tip of each root

Question 20

RAM

Answer 20

root apical meristem

Question 21

When does production of new organs occur mostly in plants?

Answer 21

post-embryonically

Question 22

The root and shoot apical meristems are specified … during embryo development.

Answer 22

• early
• by heart-stage embryo

Question 23

Meristems regenerate from…

Answer 23

differentiated tissues

Question 24

Describe explants

Answer 24

• when supplemented with adequate amounts and ratios of phytohormones, they produce new shoot and root meristems
• can generate new plants

Question 25

phytohormones

Answer 25

growth regulators

Question 26

Describe adventitious roots

Answer 26

produced from de novo formed or inactive pre-existing meristems present along the stem

Question 27

How do plants compensate
for sessility?

Answer 27

high regeneration (pretty much any organ can be regenerated)

Question 28

Describe silent meristems

Answer 28

• can be reactivated by severely damaged plant parts to restore growth
• such as after wildfires

Question 29

Why is regeneration essential?

Answer 29

grazing activity of herbivores.

Question 30

How do we visualise plant meristems?

Answer 30

• signalling reporter proteins mark meristematic cells
• fluorescent markers: GFP, RFP
• chromogenic markers: GUS
• luminescent markers (luciferase)

Question 31

Describe transcriptional reporters

Answer 31

reporter protein produced by reporter gene that follows the cell-specific promotor

Question 32

Describe a post-transcriptional/translational reporter

Answer 32

cell-specific protein reporter fusion produced from reporter gene that follows a gene, which itself follows a cell-specific promotor

Question 33

How a genetic reporters constructed?

Answer 33

fusing together promoters and/or coding ones with reporter genes

Question 34

Describe the Arabidopsis root

Answer 34

• few cell types originate from the meristematic initials
• organised around a QC
• three root tip regions: division zone, elongation zone and differentiation zone

Question 35

QC

Answer 35

• quiescent centre
• controls meristematic activity

Question 36

Describe the division zone

Answer 36

where new cells are produced

Question 37

Describe the differentiation zone

Answer 37

where adult cells acquire their final specific function

Question 38

Describe root hair cell specialisation

Answer 38

• distal part of the RAM
• epidermal cells in contact with two dorsal cortex cells elongate into a root hair with high SA:Vol
• maximise exchange of water and minerals from the soil

Question 39

Describe xylem specialisation

Answer 39

• progressive cell wall thickening and disappearance of cytoplasm
• generates lignified conduits

Question 40

Describe phloem sieve element specialisation

Answer 40

loss of citoplasmic components and perforation of transverse cell walls

Question 41

What is the role of the phloem?

Answer 41

transport of photosynthates

Question 42

Describe lateral root formation

Answer 42

• cells from the pericycle in proximity of xylem pole cells divide to generate a new LRP
• self-organises to produce a lateral root

Question 43

pericycle

Answer 43

external part of the stele

Question 44

LRP

Answer 44

lateral root primordium

Question 45

Describe the function of the cambial meristem

Answer 45

• new (secondary) xyla and phloems are produced here
• organising core directs the activity of neighbouring meristematic cells
• organiser cell differentiates into a xylem cell
• stem cell divides asymmetrically to generate a new organiser cell.

Question 46

Describe the SAM - the specifics

Answer 46

• embedded in layers of leaf primordia that protect it
• domed shape can be separated into 3 layers of meristematic cells
• OC and overlying layers visualized using fluorescent reporters (based on marker genes)

Question 47

OC

Answer 47

organising centre

Question 48

Describe the activity of the vegetative SAM

Answer 48

protrusion produced by the proliferation of the SAM form a phytomer

Question 49

Describe a phytomer

Answer 49

consists of a leaf, an axillary meristem and an internode.

Question 50

Describe the production of new leaves

Answer 50

• phyllotaxis
• plastochron

Question 51

Describe phyllotaxis

Answer 51

position of a new leaf along the stem as compared to the previous one

Question 52

Describe plastochron

Answer 52

the time interval between the production of two consecutive phyotomers

Question 53

Describe the phyllotaxis of an alternate leaf

Answer 53

180 degrees

Question 54

Describe the phyllotaxis of opposite and decussate leaves

Answer 54

90 degrees

Question 55

Describe the phyllotaxis of whorls

Answer 55

45 degrees

Question 56

Describe the phyllotaxis of spiralled leaves

Answer 56

137 degrees

Question 57

Describe the establishment of a new leaf

Answer 57

• all three layers of cells in the SAM contribute to the the tissues
• L1 generates the epidermis
• L2 produces the mesophyll parenchyma
• L3 gives rise to the vasculature

Question 58

vasculature

Answer 58

leaf veins

Question 59

Describe the determination of leaf shape

Answer 59

• gradients of growth
• direction of growth

Question 60

Describe gradients of growth

Answer 60

• generated by cell division (initially) and expansion (subsequently)
• in most dicots, a mature leaf is composed of a petiole

Question 61

Describe a petiole

Answer 61

contains the midvein and a blade (distal and proximal areas).

Question 62

Describe the direction of growth

Answer 62

controlled by how cells divide and in which direction they expand

Question 63

Describe the steps of new leaf formation

Answer 63

• founder cell recruitment (lateral and medial growth)
• distal growth (of primordium)
• blade initiation
• intercalary growth (of developing leaf)

Question 64

Describe a mature leaf

Answer 64

• midrib petiole
• B/P junction
• proximal to distal

Question 65

Describe a simple leaf

Answer 65

single undivided blade

Question 66

Describe a compound leaf

Answer 66

subunits are separated by a bladeless region

Question 67

Leaf shape is ultimately defined by …

Answer 67

serrations, lobes and leaflets.

Question 68

Within the same species simple genetic alteration can

Answer 68

• severely affect leaf structure
• e.g. tomato

Question 69

Lobes and leaflets are created by …

Answer 69

initiation during
primordium morphogenesis and differentiation

Question 70

initiation

Answer 70

persistence of meristematic regions

Question 71

Describe a transverse section of a leaf

Answer 71

• shows asymmetric cell organization
• adaxial side
• abaxial side

Question 72

Describe the adaxial side

Answer 72

• upper
• optimised for light capture and to retain water

Question 73

Describe the abaxial side

Answer 73

• lower
• suited for gas exchanges

Question 74

Describe the polarity of the leaf blade

Answer 74

• established very early in the primordium
• defined by the proximity to the SAM (adaxial closer)

Question 75

Mutations in the genes that regulate polarity generate

Answer 75

abaxialized or adaxialized leaves

Question 76

In its reproductive phase, the SAM turns into an

Answer 76

IM

Question 77

IM

Answer 77

• inflorescence meristem
• produces FMs

Question 78

FMs

Answer 78

• floral meristems
• determinate meristems that produce whorls of new organs

Question 79

Describe the floral organs

Answer 79

• concentric series
• sepals (form the calyx)
• petals (form the corolla)
• stamens
• carpels

Question 80

sepals and petals together form the

Answer 80

perianth

Question 81

What connects the sepal to the bract?

Answer 81

pedicel

Question 82

Describe the shoot architecture

Answer 82

• based on meristem termination
• vegetative meristems at terminal and lateral positions can turn into RMs
• RMs develop into alternative inflorescences depending on whether they terminate with a flower meristem or continue producing new meristems
• terminal flower meristems give rise to alternative flower architecture depending on the way they branch and produce alternative floral organs

Question 83

RMs

Answer 83

reproductive meristems

Question 84

vegetative shoot systems

Answer 84

no flowers

Question 85

Raceme

Answer 85

C2D1

Question 86

Panicle

Answer 86

C2D2

Question 87

Mutations of homeotic genes alter

Answer 87

• organ identity
• not their number (except for agamous)

Question 88

What are the main classes of homeotic gene mutations

Answer 88

A, B, C and E

Question 89

Ectopic expression of one D class gene is sufficient to

Answer 89

confer hybrid identity to petals

Question 90

‘D’ class mutants produce

Answer 90

fruits with ovules reminiscent of carpels

Question 91

Plant organs are produced…

Answer 91

post-germination from the meristematic tissues

Question 92

The meristems consist of…

Answer 92

• undifferentiated dividing cells
• non-diving core that coordinates
  their activity

Question 93

Root architecture depends on…

Answer 93

the activity of the RAM and the LRPs

Question 94

Shoot architecture is determined by

Answer 94

phyllotaxis and branching

Question 95

• At the reproductive stage of a plant’s lifecycle, the SAM produces flower meristems that terminate into flowers