Vocab - Chp 35 to 37 Plants

Question 1

Meristem

Answer 1

Tissue that remains embryonic through a plant’s entire life.
Allows indeterminate growth.

Question 2

Primary vs Secondary growth

Answer 2

Primary - growth in length.
Secondary - growth in thickness.

Question 3

Vascular & Cork cambium

Answer 3

Lateral meristem tissue arranged in a ring.
Allows secondary growth.
Vascular arises from procambium, cork cambium arises from ground meristem.

Question 4

Pneumatophores

Answer 4

Oxygen-absorbing roots that poke out of the ground - eg. in mangroves where the plant grows in oxygen-poor substrate.

Question 5

Mycorrhizal associations

Answer 5

Connection between plant roots and mycelium; exchanges nutrients between the two.

Question 6

Fibrous root system

Answer 6

Roots are arranged in a dense, shallow mat. Found in plants that are frequently grazed on by vertebrate herbivores.

Question 7

Rhizomes vs Stolons vs Tubers

Answer 7

Rhizomes - horizontal shoots just below soil surface.
Stolons - “runner” stems above the soil, as in strawberries/mint.
Tubers - enlarged rhizomes or stolons (not roots).

Question 8

Three main types of tissue in plants

Answer 8

Dermal (epidermis & periderm)
Vascular (xylem & phloem)
Ground tissue

Question 9

Periderm

Answer 9

The ‘woody’ cells that replace epidermis. Produced by cork cambium, and contains a lot of lignin for strength.

Question 10

Pith vs Cortex

Answer 10

In Eudicots:
Pith - ground tissue that is found internally of the vascular tissue.
Cortex - ground tissue that is between vascular and dermal tissue.

Question 11

Major cell types in plants
(5)

Answer 11

Parenchyma cells - default, does everything.
Collenchyma cells - scaffold.
Sclerenchyma cells - woody (lignin)
Xylem & phloem cells

Question 12

Parenchyma cells

Answer 12

A ‘normal’ plant cell:
- Thin, flexible primary cell wall; no secondary.
- Big central vacoule.
- Starch-storing amyloplasts.
- Able to divide and differentiate into other cell types.

Question 13

Collenchyma cells

Answer 13

Quick, effective scaffolding in young plants:
- Elongated, with thickened but still flexible primary cell wall.
- Just beneath epidermis in young stems.

Question 14

Sclerenchyma cells

Answer 14

Woody, basically:
- Big secondary cell wall with lignin for strength.
- Two types; boxy sclereids & elongated fibres.

Question 15

Xylem cells
(two types)

Answer 15

Water and minerals from ground up:
- Dead at maturity.

• Tracheids; Elongated, with tapered end that overlaps with the next tracheid cell. Pits in the secondary cell wall in these overlapping regions allows water to move to the next cell.
• Vessel elements; Shorter & wider than tracheids, aligned end-to-end instead of tapered. Perforation plates with holes allows water movement between elements.

Question 16

Phloem cells
(two types, kind of three?)

Answer 16

Sugars from leaves
- Alive at maturity!
- Made of sieve cells in gymnosperms & plants without seeds.
- In angiosperms, built from sieve-tube element cells. Sieve-tube elements have no nucleus/ribosomes/cytoskeleton.
- Elements connected through sieve plates with holes.

• A companion cell is next to each element, connected by lots of plasmodesmata. The companion’s nucleus/ribosomes serves the element cell.

Question 17

Vascular cambian

Answer 17

• Layer that is single cell thick.
• Forms phloem on outside.
• Xylem on inside.

Question 18

Root cap

Answer 18

“cap” of dead cells on the tip of a growing root. Made and constantly replenished by the meristem. Protects the meristem and softens the soil with mucous to help grow through it.

Question 19

Pericycle

Answer 19

Outermost layer of cells of the stele (vascular bundle) in plant roots. Non-vascular, but controls the inputs/outputs of stuff into the vascular bundle.
Also propagates development of lateral roots.

Question 20

Vascular rays

Answer 20

Radial lines of parenchyma cells that connect secondary xylem and phloem cells.
- Moves stuff between the vascular cells.
- Stores carbohydrates.

Question 21

Dendrochronology (just for fun)

Answer 21

Science of analysing a tree’s growth rings.

Question 22

Sapwood vs Heartwood

Answer 22

Sapwood - outer, younger layers of secondary xylem that transports xylem sap.
Heartwood - older, inner layers that no long transport xylem sap. Darker in colour.

Question 23

Lenticels

Answer 23

Small areas with more space between cork cells.
Allows cells on the inside to exchange gases for respiration.

Question 24

Pattern formation

Answer 24

Development of specific structures in specific locations - eg. dermal tissue on the outside, vascular on the inside.

Question 25

Position-based mechanism
(pattern formation)

Answer 25

Plant cell differentiation is determined later in the cell’s life based on where it ends up, rather than early on like in animals.

Question 26

Leaf primordium

Answer 26

Tiny groups of cells that form new leaves.
(Floral primordia form flowers)

Question 27

ABC hypothesis

Answer 27

A model of three genes regulating the spatial pattern in flowers.

Question 28

Morphogenesis (in growth)

Answer 28

Development of body shape and organisation.

Question 29

Cell differentiation (in growth)

Answer 29

Differing gene activation allows cells to assume different functions.

Question 30

Phyllotaxy

Answer 30

Arrangement of leaves on a stem.

Question 31

Apoplast

Answer 31

Everthing external to plasma membrane - cell walls, extracellular spaces, interior of dead cells like tracheids.

Question 32

Symplast

Answer 32

All cytosol and plasmodesmata.

Question 33

Three routes of short distance transport

Answer 33

Apoplastic - extracellular spaces
Symplastic - within cells, through plasmodesmata
Transmembrane - within cells, crossing membranes

Question 34

𝛙 definition

Answer 34

Water potential, with units of megapascals.

Question 35

𝛙 equation

Answer 35

𝛙 = 𝛙s (solute potential) + 𝛙p (pressure potential)

Solute potential is negative; more solutes decrease water potential.
Pressure potential can be positive or negative, relative to atmospheric pressure.

Question 36

Ion that controls guard cell opening/closing

Answer 36

K+

Question 37

Three main factors that causes stomata to open

Answer 37

• Light
• Low CO2 within the leaf
• Internal circadian rhythm

Question 38

Abscisic acid

Answer 38

Hormone released during drought stress. Causes stomata to close, and inhibits photosynthesis.

Question 39

Xerophytes

Answer 39

Plant adapted to arid climates.

Question 40

Translocation

Answer 40

Transport of nutrients in the phloem.

Question 41

Soil horizon

Answer 41

Soil layers with distinct properties.
Topsoil is the A horizon.

Question 42

Loams

Answer 42

Soil with somewhat equal amounts of sand/silt/clay, most fertile.

Question 43

Charge in soil particles

Answer 43

Most soil particles are negatively charged.
This also means some nutrients (nitrate, phosphate & sulphate) are lost easily, since they won’t bind to negative particles.

Question 44

Cation exchange

Answer 44

Positively charged minerals (bonded to negative soil particles) are released and made available by the plant when displaced by H+.

Question 45

Role of phosphorous in plants
(3)

Answer 45

Component of:
- DNA/RNA
- ATP (phosphate)
- Phospholipids

Question 46

Role of nitrogen in plants
(3)

Answer 46

Component of:
- DNA/RNA
- Amino acids
- Chlorophyll

Question 47

Role of potassium in plants
(2)

Answer 47

• Cofactor of many enzymes
• Helps maintain turgor