Unit 2 Topic 4Ai Plant Structure and Function Flashcards

Question

What can sclerenchyma cells develop into

Answer 1

1. sclerenchyma fibers 2. sclereids

Answer 2

long cells found in bundles / cyliners around the outside of a stem / root

Answer 3

- lignin deposited on the cell walls in spiral or ring pattern ==> strong but flexible - lignification causes cell contents to die ==> water cannot pass through lignin, cell cannot get nutrients - cause fibres to become long and hollow tubes - once cell wall is lignified => cell can no longer grow => plant growth is higher up in the stem - strength is based on their length and degree of lignification

Answer 4

- thinner areas of sclerenchyma fibers cell wall without lignification - allow the communication and exchange of fluid between the cells

Answer 5

- star-shaped cells / irregular - completely impregnated with lignin - very tough cells found in groups thorughout the cortex of the stem / individual in plant tissue

Answer 6

outermost part of the stem between the epidermis and vascular

Answer 7

1. transport water and dissolved minerals from the roots to the photosynthetic parts of the plant 2. provide structural support to the plant

Answer 8

1. tracheids 2. xylem vessels / vessel elements

Answer 9

- exists in all vascular plants - long and thin - tapered end walls (becoming smaller at the end) - arranged end-to-end, connected by pits - less efficient water transport

Answer 10

- exists in certain vascular plants - hollow and elongated - empty lumen => less resistance - perforated end-walls, end walls are **fused** together - more efficient water transport

Answer 11

- larger diameter - perforated end walls

Answer 12

The first-formed primary xylem tissue during plant growth, developing early when the plant organ (stem or root) is still elongating

Answer 13

- cell walls not fully lignified = can stretch and grow - cellulose microfibrils in the wall of xylem vessels are **arranged vertically** in the stem = increase strength of tube, allow tube to resist compression forces from the weight of the plant pressing down to it

Answer 14

- increasing deposition of lignin to the cell wall of the xylem tissue (cellulose not strong enough to resist the weight of the growing plant) - cell becomes impermeable to water and other substances (can be used for transport) - stronger and more supportive - cause xylem cells to die and become hollow - forming metaxylem

Answer 15

- holds the cellulose microfibrils together by keeping them in their parallel arrangement - xylem does not collapse despite the decrease in the hydrostatic pressure inside the tube due to transpiration

Answer 16

- lignified cell walls cause it to become impermeable to substances - blocking substance transport between xylem cells and outer environment - cytoplasm, chloroplast starve = organelles to die = xylem cells die and become hollow - forming a continuous column

Answer 17

- lignified xylem tissue consisting of mature xylem vessels - end walls between xylem cells broken down ==> forming hollow tubes from the roots to the tip of stem and leaves

Answer 18

- do not contain any cytoplasm or organelles (do not slow down the flow of water) - do not have end plates (mass flow of water and dissolved solutes are not impeded)

Answer 19

- supported by cohesive (between water molecules) and adhesive (between water molecules and cellulose walls) forces - small regions which are not lignified (pits, only cellulose): allow for the lateral movement of water and minerals between xylem vessels

Answer 20

- living tissue made of many phloem cells joined together to make very long tubes that run from the tip of the shoot to the end of the roots - not lignified, no support function

Answer 21

- located towards the centre of the stem, forming central vascular bundle - surrounded by phloem tissue - often arranged or forming a ring or several ring within the stem

Answer 22

- found between the xylem and outermost layer of the stem - forming ring around xylem

Answer 23

- typically located in the centre - central vascular bundle - radiate outward - youngest xylem tissue towards the center, older towards the periphery

Answer 24

- arranged in ring surrounding the xylem - allows for efficient transport of sugars and other organic compounds produced in the leaves to the roots for storage or growth

Answer 25

- found in midrib and veins - extending throughout leaf lamina - provides structural support - facilitates the transport of water and minerals absorbed by the roos to the leaf cells

Answer 26

- located adjacent to the xylem in the veins - transports organic compounds such as sugars produced during photosynthesis from the leaves to the other parts of the plants

Answer 27

transport organic compounds (surcrose, amino acids) from the sources to the sinks (depends on season) needed for growth or storage | (organic compound are dissolved in water to form sap)

Answer 28

Transport can occur both up and down the plant and is an active process - movements of sugars and photoassimilates (products of photosynthesis) from the sources to sinks

Answer 29

1. sieve tube element 2. companion cells

Answer 30

- many seive tube members - living cells with no nucleus - tonoplast, and some other organelles - break down as the gaps in sieve plates are made, allows phloem sieve tubes to become filled with phloem sap

Answer 31

cyroplasmic membrane surrounding large vacuoles within plant cells

Answer 32

- walls between phloem cells are perforated - creating specialised sieve plates - allows phloem sap to flow through holes in the sieve plates

Answer 33

- allow phloem cells to remain alive, supporting activity of phloem cells - involved in loading and unloading sugars into phloem sieve tube elemnets

Answer 34

- infoldings in the cell membrane: increase surface area for transport sucrose into the cell cytoplasm - mitochondria: undergo aerobic respiration to supply ATP for the active transport of organic compounds - linked to sieve tube by plasmodesmata

Answer 35

cytoplasmic bridges between plant cells allowing communication between cells

Answer 36

parenchyma (for storage), sclerenchyma fibers (strengthening)

Answer 37

- meristematic tissue - layer of unspecialised cells between the xylem and phloem - divide to give rise to more specialised cells that form both xylem and phloem

Answer 38

- turgid parenchyma cells in the center of the stem provide most of the support - sclerenchyma, collenchyma tissues also provide support - can wilt if too much water is lost by transpirtion if they are young

Answer 39

- more lignin is deposited in the xylem tissue to increase support as they grow

Answer 40

- lignified xylem makes up most of the tree trunk - living cells around the cambium (undergo celll division) are on the outside of the trunk - new ring of vascular tissue is made every year

Answer 41

1. apoplastic pathway (extracellular pathway) 2. symplastic plathway (intracellular pathway) can occur simultaneously

Answer 42

- water moves from cell to cell along cell walls by diffusion

Answer 43

water moves from cell to cell through plasmodesmata and cytoplasm of cells by osmosis

Answer 44

loss of water vapour from leaf surface due to evaporation

Answer 45

- water in mesophyll cells evaporate - water vapour formed in the intercellular spaces diffuses out of the leaves through stomata - water loss from mesophyll cells are replaced by water drawn from xylem vessels into mesophyll cells by osmosis - creating a transpiration pull to draw water up - cohesive force between water molecules and adhesive force between water molecules and xylem vessel cause water to moveup xylem vessel in a continuous flow

Answer 46

- cellulose molecules linked by hydrogen bonds - microfibrils - layers / sheets of microfibrils - microfibrils arranged in mesh / criss-cross / at different angles to each other

Answer 47

- storing water and minerals - maintaining cell turbidity

Answer 48

- stores starch in plants - converts it back to glucose when the plant needs it

Answer 49

- chloroplast - cell wall - amyloplast - tonoplast - plasmodesma - large vacuole

Answer 50

Similarities - both have pits, cellulose, dead hollow cells, secondary cell walls and lignin Differences - no end walls in xylem

Answer 51

- creates more space inside the vessel for transporting water

Answer 52

cellulose and lignin

Answer 53

Similarities - they both have cell walls Differences - parenchyma cell wall is made of cellulose; xylem cell wall is made of cellulose and lignin - no cytoplasm and vacuoles in xylem (a lot in parenchyma)

Answer 54

- vessel are hollow tubes - lignin needed to add strength to the vessel - xylem involved in transport of water - lignin needed to waterproof the vessels

Answer 55

xylem vessels only

Answer 56

not found in both

Answer 57

Similarities - both fibres contain cellulose in cell walls - both have tubular structures - both do not contain a nucleus Differences - phloem sive tubes have sieve plates / perforated end walls whereas xylem vessel have no end walls - phloem sieve tubes contain cytoplasm and are not hollow, whereas xylem vessels do not contain cytoplasm and are hollow - phloem sieve tubes contain no lignin / secondary thickening while xylem do - phloem have plasmodesmata whereas xylem have pits

Answer 58

- transport / translocation of sucrose / amino acids - from source to sink

Answer 59

- photosynthesis to keep cool - as a transport medium - support / turgor - hydrolysis

Answer 60

Nitrates = amino acids = proteins like enzymes magnesium = chlorophyll calcium = calcium pectate in the middle lamella in cell wall

Answer 61

- movement of water from soil through root hair cells (osmosis) - across the root to the xylem, up the xylem - across the leaf until water is lost by evaporation from leaf cells (in the form of water vapour) - water vapour diffuses out of the stomata down a concentration gradient

Answer 62

upward pulling force created due to transpiration on leaf surface that draws water up xylem vessels

Answer 63

- absorption of water increases osmotic pressure in root cells - root pressure pushes water and mineral ions upward in xylem vessels

Answer 64

regulate the amount of water lost through transpirtion by opening and closing the stomata

Answer 65

- light intensity is low, stomata closes to prevent water loss through transpiration - temperature is lower, less steep concentration gradient - increased humidity, less steep concentration gradient - reduced airflow

Answer 66

1.sucrose secreted into phloem sieve tubes through **companion cells** at source by **active transport** - increase **sugar concentration** in phloem sieve tube - decrease in **water potential** in the source end of phloem sieve tube - water is drawn from xylem to phloem sieve tube by **osmosis** - entry of water **increases hydrostatic pressure** in the source end of phloem sieve tube 2.hydrostatic pressure - hydrostatic pressure in source end of phloem sieve tube is **larger** than the sink end of the tube - **force mass flow of phloem sap** along phloem sieve tube from the source towards the sink 3.sugar converted into starch for storage / consumed at sink - sugar **diffuses** from phloem sieve tube to sink - **decreases in water potential** in sink - water is drawn from phloem sieve tube by **osmosis** - water moves out by osmosis, **decrease hydrostatic pressure in sink end** of phloem sieve tube

Answer 67

- less fossil fuels are used - plants can be replanted for the next generation - plant fibres are biodegradable (can be broken down by microbes, minimising environmental pollution) - extracting and processing oil is expensie and difficult compared to growing and processing plants (easier for developing countries)

Answer 68

- not as strong typically

Answer 69

- fibres are very long long sclerenchyma cells and xylem tissue - exists in bundles of fibres which are stronger than individual cells - fibres not easily broken by pulling (under tension) - cellulose and lignified cellulose are not easiily broken down by chemicals or enzymes

Answer 70

- matrix of pectates - other compounds around fibres (including lignin)

Answer 71

process using natural decomposers to break down materials around fibres (maxtrix of pectates) - can be replaced by manufacturing processes using chemicals and enzymes to speed up the process

Answer 72

- produced in the form of almost pure fibers packed around seeds - retting / other treatment are not needed - cotton fibre cells must be processed (spinning) to increase strength of each fibres

Answer 73

pulls out short, single fibres and twists them together to form a long, continuous thread - increases strength of each fibres

Answer 74

- cotton can absorb water - more breathable and comfortable (?)

Answer 75

- made of at least two materials combined together - with different properties from either of the constituent materials

Answer 76

- lignified cellulose fibers embedded in hemicelluloses and lignin

Answer 77

1. cellulose fibres = very resistant to compression (squeezing by weight) 2. flexible due to intermeshing cellulose fibres 3. good insulator of heat 4. sustainable resource if planted 5. can be carbon neutral when wood is burned

Answer 78

resistant to compression - weight-bearing in buildings - supported columns, horizontal beams

Answer 79

- takes carbon as it grows - releases carbon as it burns

Answer 80

- difficult to extract because the matrix around cellulose fibers contains a lot of lignin - need to be soaked in very strong alkalis (caustic soda) to produce a pulp consisting of cellulose and lignified cellulose in water => pressed onto frames ==> dry to make paper

Answer 81

1. use five types of plastic / fibres of equal length 2. clamp the strips between two stands and add bubble wrap in a tray below the plastic strips 3. add a 10g slotted weight loop in the middle of the strip, continue adding 10g slotted weight onto the hook until the plastic / fiber breaks 4. record the total mass required to break 5. repeat for each type of plastic / fibre for at least 3 times and calculate the mean

Answer 82

- made from biological polymers (starch, cellulose)

Answer 83

1. polylactic acid (PLA) 2. thermoplastic starch 3. poly-3-hydroxybutyrate (PHB) 4. cellulose-based plastics

Answer 84

- mostly produced from maize / sugar cane - similar properties to polyethene, but biodegradable - computer casings, mobile phones, drinking cups

Answer 85

- mixture of starch extracted from potatoes and maize and other compounds like gelatine - smooth and shiny plastic - pharmaceutical industry to make capsules containing drugs - easily swallowed and digested

Answer 86

- made from products of sugar industry - stiff biopolymer like polypropene - ropes, bank notes, car components

Answer 87

- wood pulp - food wrappers

Answer 88

1. high sustainbility (replaced at sustainble rate) 2. biodegradable (broken down by microorganisms, decrease amount of plastic pollution) 3. burning bioplastics (release energy, avoid production of methane)

Answer 89

1. economic considerations (small cost advantages, technology still new) 2. ethical consideration (limited food crops dilemma, not always have same useful properties)

Answer 90

1. long to increase SA for absorption (increase rate of transport) 2. many mitochondria (aerobic respiration to produce ATP energy, active transport of mineral ions to root hair cells)

Answer 91

- water and mineral ions are absorbed through root hairs on the root and travel up the stem in xylem vessels - mineral ions are absorbed by active transport - water absorbed by osmosis

Answer 92

inside root hair cells - higher solute concentration - lower water potential outside root hair cells - lower solute concentration - higher water potential

Answer 93

1. photosynthesis 2. transport medium for minerals (dissolve polar substances like mineral ions) 3. maintain turgidity to support plants 4. cooling effect (carries heat as it evaporates, decrease chance of enzyme denaturation) 5. hydrolysis

Answer 94

- water moves into vacuoles of cells by osmosis - cytoplasm becomes pressed against cell walls, making them turgid

Answer 95

- forces between water molecules - allow for movement of water from roots to leaves of plants in transpiration stream due to transpiration

Answer 96

- forces between water molecules and hydrophilic molecules - water molecules attracted to cellulose in the cell wall of xylem vessels and this contributes to the formation of the transpiration stream

Answer 97

- no air space between clay / sand particles as they are very close to each other - mitochondria inside root hair cells cannot receive oxygen from the atmosphere - cannot undergo aerobic respiration to produce ATP energy - less or no active transport of mineral ions into the root hair cells - may die

Answer 98

- oxygen cannot reach the roots well because water occupies the spaces between soil, instead of oxygen, so less airspace is available

Answer 99

- synthesis of calcium pectate in the middle lamella of plant cell walls (holds microfibrils in cell walls together, holding neighboring plants cells together) - important for the permeability of membranes

Answer 100

- synthesis of chlorophyll (proves green color, capture light to convert co2 and water into glucose and oxygen in photosynthesis) - activation of plant enzymes, synthesis of nucleic acids

Answer 101

- growing points die back - yellow and crinkly leaves / young leaves become yellow

Answer 102

- less chlorophyl produced, plant die as cannot photosynthesis - older leaves develop yellow areas, stunted growth

Answer 103

- synthesis of amino acids in protein, nucleic acid (DNA / RNA), chlorophyll, enzymes where nitrate ions are needed - important for plant growth, production of fruit and seeds (ignored in pp)

Answer 104

- older leaves yellow and die - stunted growth

Answer 105

purple patches on leaves

Answer 106

curled-up leaves with dark-colored edges

Unit 2 Topic 4Ai Plant Structure and Function Flashcards

(132 cards)