Michaelmas Flashcards

Question

Outline the two main hypotheses about the development of photosystems and their evolutionary relationships.

Answer 1

- Two photosystems developed in a single organism, with the loss of one over time. - Two classes of photosystems developed independently, followed by genetic fusion or lateral transfer of genetic material.

Answer 2

- PSII derived from purple bacteria. - PSI derived from green sulfur bacteria or heliobacteria.

Answer 3

- Double membrane resembling cyanobacteria. - Double-stranded DNA, uncommon for organelles. - Promoters resembling prokaryotes (lacking TATA, having consensus sequences at -35 and -17). - 70S ribosomes like prokaryotes. - Division process similar to bacteria.

Answer 4

Similarities: - Presence of plastocyanin in the thylakoid lumen. - Thylakoid membranes containing Light Harvesting Complex (LHC) and Reaction Center (RC). - Stroma - Photosynthetic pigments Differences: - Fewer genes in chloroplasts (cDNA) compared to cyanobacteria (entire genome). - Chloroplasts have additional strucures, such as starch granules - Chloroplasts have larger more complex organelles - Use different photopigments

Answer 5

- An obligate parasitic plant. - Lost its photosynthesis genes. - Smaller chloroplast DNA (70kb) compared to non-parasitic plants (217kb in germaniums).

Answer 6

1. Filamentous temperature sensitive (fts) gene: form long filaments at restrictive temperatures 2. Minicell (MinD): Important in regulating cell division, can lead to the production of larger cells as no division ring is formed 3. Cav1: unable to move chloroplasts in response to high light, so can lead to photobleaching

Answer 7

Progenitor: Proplastid Chloroplasts: Located in leaves, carry out photosynthesis. Amyloplast: Stores starch. Elaioplast: Stores oil.

Answer 8

Form stomules (stroma-filled tubules). Act as signaling structures and increase surface area (SA).

Answer 9

RC processes: - Electron transfer from donors and acceptors to PSI. - Proton gradient across the membrane enables ATP synthesis. Pigments: - Chlorophyll and Carotenoids. - Wavelength absorption differences in vitro and in vivo due to leaf structure. - Emerson Enhancement effect requires both PSI (700nm) and PSII (680nm) for high photosynthesis rate

Answer 10

Chlorophyll Structure: - Porphyrin head with Mg and 4 N for delocalized electrons. - Phytol chain for anchoring to the lipid membrane. Differences: - Chlorophyll b has a formyl group instead of methyl, increasing absorption of blue. - Bacteriochlorophyll has fewer double bonds, absorbing longer wavelengths.

Answer 11

- Triple banded absorption. - Alternating single and double bonds. - Serve in light harvesting and energy dissipation (NPQ)

Answer 12

1. Light energy raises from S1 to excited S1*. 2. Energy is transferred by Resonance Energy Transfer (RET). Resonance Energy Transfer: - Transfers from chlorophylls to the special pair - Works for molecules in close proximity. - Depends on correct molecular orientation.

Answer 13

- Major distal LHCs (L + M + S), form a trimeric shape, binding 60% of chlorophyll. - Minor distal LHCs are monomeric and bind fewer chlorophylls. - Inner antenna complex (CP47, CP43) binds 50 chlorophylls each. - PSII core is dimeric with mirror symmetry.

Answer 14

1. Electron from the reaction center goes to pheophytin. 2. Pheophytin transfers to Qa. 3. Qa passes the electron to Qb and Plastoquinone. 4. Plastoquinone attracts 2H+ and forms Plastoquinol (PQH2).

Answer 15

1. P680* oxidizes tyrosine. 2. Tyrosine is reduced by the manganese cluster. 3. Manganese gains electrons from the splitting of water.

Answer 16

- Found in PSII - Splits water to form oxygen and protons (H+). -Structure: 4 Manganese and Calcium atoms. - Formation of oxygen requires 4 oxidation events.

Answer 17

- Experiment to test how water is excited to produce oxygen - Flashes of light showed periodic O2 yield with a peak on the third flash. - Periodicity of 4 flashes. Conclusion: S rests in S1 state, and at S4 state, it releases oxygen (reached at the third flash).

Answer 18

- Plastoquinol (PQH2) passes it Cytb6f complex THEN EITHER: 1. Through Rieske protein’s Iron-sulfur clusters to Plastocyanin (PC) leading to PSI. 2. To cytb563 where plastoquinone picks up 2H+, increasing the H+ gradient.

Answer 19

Definition: Light-dependent reduction in the light-dependent reaction of photosynthesis. Occurs when light capture exceeds ATP and NADPH use by the CBB cycle. Effects: - Over-reduction of Electron Transport Chain (ETC) leading to PSII and D1 protein damage. - Production of Reactive Oxygen Species (ROS) bleaching chlorophyll. - Superoxide production leading to H2O2 formation, attacking lipids, nucleotides, and proteins.

Answer 20

1. Dynamic/Reversible/Protective Photoinhibition: - Reduces photosynthesis efficiency to avoid damage. 2. Chronic Photoinhibition: - Greater damage that is expensive to repair. - Sometimes considered irreversible. - Associated with much lower rates of photosynthesis.

Answer 21

1. Leaf Structure - Shade leaves: Invest less in photoprotection. - Sun leaves: Invest more, are better protected from light. 2. Energy Dissipation: - Non-photochemical quenching (NPQ): Conformational change and heat dissipation by carotenoids. - Xanthophyll cycle: Conversion from violaxanthin to zeaxanthin.

Answer 22

- Converts violaxanthin to zeaxanthin by de-epoxidases. - Zeaxanthin is more photoprotective because it is less efficient at transferring energy - Higher xanthophyll to chlorophyll ratio in sun leaves. - Operates on a diurnal cycle. - Operates within minutes.

Answer 23

1. Over-expression of β-carotene hydroxylase leads to more xanthophyll pigments, enhancing the response to light. 2. Mutations in npq4 (PsBs) or npq1 (de-epoxidase) result in lower productivity. - PsBs is an important signalling receptor for NPQ, upregulation leads to better NPQ - Wild type (WT) performs significantly better under varied light intensity. 3. Over-expression of xanthophyll cycle enzymes and PsbS improves the plant's ability to track light fluctuations and enhances productivity.

Answer 24

1. Rapid Leaf Movements: Oxalis (shamrock) responds to excessive light by flipping down rapidly. 2. Reflectance: - Changes in trichrome (hair) abundance responding to leaf moisture. e.g. Atriplex hymenelytra adjusts reflectance based on leaf moisture.

Answer 25

1. Leaf Angle: - Increases in response to less water. e.g. Grasses maintain a relatively angled position. 2. Leaf Hairs: - More hairs increase reflectance. e.g. Encelia exhibits differences in hair abundance between moist habitats and desert environments. Farinosa in desert, Californica in moist habitats

Answer 26

Slow Sunflecks: Movement of the sun. Fast Sunflecks: Rapid leaf fluttering. Importance: Allows sunlight to reach the understorey canopy Evidence - Adenocaulon bicolor (American trailplant): -Measures the rate of assimilation. - At low light levels, O2 production slightly exceeds O2 uptake for respiration. - Flashes of light significantly increase assimilation rate.

Answer 27

Heliotropism: Tracking the sun. Diahelitropism: Leaves that remain perpendicular to the sun's rays to maximize light capture. Parahelitropism: Leaves that remain parallel to the sun's rays. - Perpendicular orientation absorbs the greatest flux

Answer 28

Germinators: Shade-intolerant plants germinate when a gap forms. Persistors: Shade-tolerant plants germinate and wait until a gap forms before developing.

Answer 29

Blue bells flower in early spring, before leave on the trees begin to form and block out light Characteristic indicates convergent evolution, where both monocot and dicot species adapt to grow in different seasons.

Answer 30

Higher LAI in erectophiles like grasses that have leaves at a high angle, from horizontal Changes in LAI during the Green Revolution have led to more gradual light attenuation, benefiting lower plants.

Answer 31

1. Leaf Angle: Varies within species depending on location. 2. Leaf Nitrogen: Higher concentration in top canopy leaves. 3. Leaf Age: Older leaves have a declining photosynthetic rate due to self-shading and resource re-allocation. 4. Leaf Thickness: Affects gas diffusion, thicker leaves may be less efficient but retain light better.

Answer 32

-Higher concentrations in top canopy leaves due to higher productivity. - More chlorophyll, which is nitrogen-rich. Effect on Net Photosynthesis: - Increasing leaf nitrogen increases net photosynthesis in some plants.

Answer 33

- Maximum photosynthesis rate declines with age. - External factor: Reasons include self-shading and resource re-allocation to younger leaves.

Answer 34

- Leaf structure, including thickness, nitrogen content, angle, and age, is crucial in determining photosynthetic capacity. - Different combinations of these factors lead to compatible or incompatible outcomes. -For example, long-lived, thick leaves are subject to herbivory and are metabolically expensive, making them highly unlikely.

Answer 35

- Transport mainly Triose Phosphates (TPs), derived from 3-PGA, exchanging TPs for Pi. Experiment sourcing 5C and 6C: shows specificity, TPT moves 3C, not 5C or 6C sugars. - Transports via a ping pong mechanism NOTE: TPT relays information about relative rates of photosynthesis and sucrose synthesis by transporting phosphate.

Answer 36

1. Combination to form Fructose-1, 6-bisphosphate. 2. Lose a Pi to become Fructose 6 phosphate (F6P). 3. Conversion between glucoses to form Glucose-1-phosphate. 4. Formation of UDP-glucose by UDP-G pyrophosphorylase. 5. Conversion to sucrose by SPS and SPP

Answer 37

-- Inhibition of FBPase by F-2,6-BP: 1. Enzyme PFK II produces F-2,6-BP from F6P 2. PFKII is activated by Pi, and F6P, and inhibited by DHAP and 3PGA - High concentrations of F-2,6-BP inhibit FBPase, reducing F6P production, and subsequently, UDP-Glucose. - High F-2,6-BP concentrations occur at night.

Answer 38

1. Supply of radio-labelled carbon and subsequent Electrophoresis showed the production pathway from UDP-glucose-> Sucrose P-> Sucrose 2. Bifluorescence complementation- half of the GFP bound to SPS and the other to SPP. Binding and formation of the complex led to fluorescence being emitted 3. Increase in one (e.g. SPP) led to the increase in the presence of the other SPS

Answer 39

- Insoluble carbon store in algae and plants. - Has a very ordered structure. -Energy for seed germination. - Regrowth after fire or herbivory. - Food staples like maize, rice, potato, etc.

Answer 40

Made up of amylose and amylopectin Amylose: - α-1,4 glucan bonds. - Few branches. Amylopectin: - α-1,4 glucan bonds and α-1,6 glucan bonds. - Highly branched.

Answer 41

Transitory Starch: Generated in photosynthetic cells (chloroplasts). -Main pathway involves ADPG pyrophosphorylase and starch synthase. - Controlled by F-1,6-Bpase activity and sucrose synthesis rates. Storage Starch: - Generated in non-photosynthetic cells (amyloplasts in roots, etc.). - Synthesis involves the formation and transport of hexose phosphate. - Importance highlighted in mutants like shrunken1 maize with a mutation in sucrose synthase. ~~Sucrose synthesis and transport play crucial roles in controlling starch synthesis

Answer 42

Glucose 1-P → ADPglucose → α 1,4 glucan. - Involves ADPG pyrophosphorylase (ADPG PPiase) and starch synthase. Evidence: Single-point mutations in the gene encoding ADPG PPiase led to a significant reduction in starch production.

Answer 43

1. Degradation of sucrose to F-6-P initially by sucrose synthase/invertase. 2. Transformation of UDPG to F6P via UDP-G PPiase. 3. Hexose transported into plastid and converted to ADPG by ADPG PPiase, then to starch Transport into plastid: Membrane hexose-P translocator with strict counter-exchange with Pi.

Answer 44

Water-soluble, non-reducing polymers of fructose. - Synthesis induced by high sucrose levels. - Implicated in cold and drought tolerance. - Difficult to digest, used as a fiber supplement.

Answer 45

- Triacylglycerides (TAGs) or Triglycerides. - Glycerol backbone + 3 Fatty acid tails. - Produce more ATP per unit carbon compared to carbs. Uses: - 25% of dietary calories. - Biodiesel production through transesterification. - Lubricants - Energy storage for germination

Answer 46

Glycerol Backbone Synthesis: - From GAP and DHAP (formed by sucrose hydrolysis) Fatty Acid Synthesis: - From acetyl CoA through decarboxylation of pyruvate. - Different lengths and C=C configurations give different properties.

Answer 47

TAG Synthesis occurs at the ER - Transesterification of 3 FAs onto glycerol backbone. - Catalyzed by Acyltransferases (AT), including GPAT, LPAT, and DGAT. - Sequentially added on by the three enzymes

Answer 48

Transcription factor WRINKLED 1 (WRI1) regulates fatty acid synthesis. + acts as a master regulator Evidence: - wri1-1 mutants in Arabidopsis show low lipid content, leading to wrinkling. - Overexpression of WRI1 in maize increases seed oil content.

Answer 49

Storage of TAGs: Oil bodies bud off the ER, having a monolayer of phospholipids encapsulating TAGs. Mobilization Process (Glyoxylate Cycle): 1. Hydrolysis by lipase releases fatty acids from glycerol. 2. Glycerol is metabolized by glycolysis. 3. Fatty acids undergo β-oxidation and enter the Glyoxylate Cycle, which is more carbon-efficient than the TCA cycle.

Answer 50

Glyoxylate cycle is more carbon efficient and uses the enzymes - Isocitrate Lyase - Malate synthase And forms a glyoxylate intermediate, from isocitrate, which bypasses the CO2 losing reactions in the TCA cycle Link: Enzyme PEP carboxykinase produces phosphoenolpyruvate (PEP) from malate

Answer 51

Modified peroxisomes located next to oil bodies. Regulation: 1. Coarse gene expression control, such as the master regulator WRINKLED 1. 2. Fast response to changes in lipid levels, leading to adjustments in enzyme activity.

Answer 52

Responsive to surroundings and affected by multiple factors. Also its involvement with various other processes

Answer 53

Excitation energy goes to 3 processes: - Photochemistry - Dissipation as heat (NPQ) - Re-emission (fluorescence)

Answer 54

Competing Fates between fluorescence, photochemistry, and heat (NPQ) pathways. The sum of these pathways always adds up to one.

Answer 55

Fo: Minimum fluorescence in a dark-adapted state. Fm: Maximum fluorescence level, from base level. Fm': Max fluorescent yield after the first flash. ΦPSII: Maximum PSII efficiency (effective quantum yield). NPQ: Non-Photochemical Quenching.

Answer 56

ΦPSII = (Fm - Fo) / Fm NPQ = (Fm - Fm') / Fm' Operating ΦPSII = (Fm' - Fo') / Fm'

Answer 57

- Rate of change of ΦPSII efficiency decreases rapidly in high light. - Rate of change of NPQ activity is slower but still responsive to high light. -- First exposure to light is when all reaction centres are open and NPQ not yet induced, so measures Fm, also used to test the health of a plant

Answer 58

Decrease in CO2 for the Calvin-Benson-Bassham (CBB) cycle leads to a decrease in ΦPSII. More energy will be released via the NPQ or fluorescence pathway

Answer 59

- Enclose leaves in a gas exchange cuvette. - Measure gas composition before and after to determine steady-state rates of gas exchange. - Calculate net release by multiplying by flow rate and dividing by measured leaf area. REMEMBER: Need to standardize for the leaf area

Answer 60

Gas exchange controlled by the opening and closing of stomata. Stomata are controlled by guard cells, which change due to turgor pressure

Answer 61

1. Diffusion rate 2. Biochemistry - Rubisco capacity @low CO2 limiting - RuBP regeneration @intermediate CO2 - Use of products @ high CO2 limiting By modelling A (CO2 assimilation) against [CO2] this eliminates the effect of diffusion Michaelis- Menten Graph plot shows how well the Rubsico limiting line fits for low CO2

Answer 62

Crucial for photosynthesis Important for nutrient transport Deficiency leads to stunted growth

Answer 63

- Water moves along the water potential (ψ) gradient. - Biggest change in ψ is due to water evaporation (from -3 to -30) at the leaf. - Water potential is influenced by osmotic pressure, matric potential, and solute potential.

Answer 64

Water Potential: Tendency for water to move. Osmotic Pressure: Pressure required to stop the movement of pure water. Matric Potential: Caused by adhesion of water molecules to non-dissolved structures. Solute Potential: Chemical potential energy of water, numerically equivalent to osmotic pressure.

Answer 65

Tissue withdraws water by accumulating solutes, reducing water potential. Experiment: Pressure bomb - cut stem, alter pressure until water comes out, pressure required equals tension in the stem holding water.

Answer 66

Field Capacity: Water retained in capillaries. - Continuous water loss leads to wilting when matric potential is too negative. - Dry soil has a strong negative matric potential.

Answer 67

- Increase in inorganic ions drives water into the root steele, creating positive root pressure. - Guttation is the exuding of water onto the surface through hydathodes, aiding in temperature control, nutrient uptake, and maintaining turgor pressure. Usually occurs at night, different to morning dew because extruded from plant and not formed by condensation

Answer 68

- Temperature control - Repair cavitation - Maintain water flow - Maintain turgor pressure

Answer 69

Increasing solute concentration makes water potential more negative. Examples: Proline, glycine, mannitol - compatible solutes that don't disrupt protein hydration.

Answer 70

Tracheids: Long, thin, overlapping cells. Vessels: Short, wider cells with perforated end plates. Structure influences hydraulic conductance, with wider vessels being more efficient but potentially riskier. - Gymnosperms (pines and conifers)

Answer 71

Hydraulic conductance is proportional to the fourth power of vessel radius (Poiseuille’s Law). Seasonal variation includes wider vessels during growing seasons.

Answer 72

Cavitation: Formation of an air pocket, leading to water flow blockage. Causes: High tension in the water column, freeze-thaw cycles, pathogens. Emboli: Air bubbles blocking vessels. - Plants mitigate cavitation through redundant vessels and the rate of embolism repair.

Answer 73

1. Gas Repair: Gas is forced back into solution by increasing local pressures. 2. Xylem Parenchyma: Provides ions and sucrose to xylem, lowering water potential. 3. Pit Geometry: Ensures synchronous filling, preventing air bubble reforming.

Answer 74

Aquaporins control water movement through mesophyll cells. - Too much water in mesophyll cells can affect CO2 uptake. So control is required Evidence: Inhibitors like mercuric chloride have effects similar to adding ABA.

Answer 75

Aquaporins can close to prevent guttation fluid from flooding mesophyll cells. This helps maintain proper water balance and prevents potential issues with CO2 uptake.

Answer 76

- Low stomatal conductance - Ability for osmotic adjustment - Hydraulic conductance - Turgor pressure

Answer 77

Climate: Wet winters, dry summers. Sclerophylls (Resprouters): Hard leaves, resprout after fire. Malacophylls (Seeders): Soft leaves, regrow from seeds after fire. Geophytes (Bulbs): Stay underground as bulbs to avoid drought.

Answer 78

Shows precipitation and temperature of a location. If temperature exceeds precipitation, evaporation is high, indicating a dry climate.

Answer 79

Sclerophylls - Hard leaves - Water savers - Low CO2 assimilation - Great WUE Malacophylls - Soft leaves - Water spenders - HighCO2 assimilation - Low WUE

Answer 80

Drylands: Areas with average rainfall less than potential moisture loss through evaporation and transpiration. Aridity Index: Ratio of Precipitation (P) to Potential Evapotranspiration (PET)

Answer 81

Hyper-arid: Water deficit all year round, no crop growth without irrigation. Semi-arid: Water deficit for most of the year, short periods of crop growth (e.g., Almeria, Spain). Dry Sub-humid: Alternates between drought and excess water (e.g., Australia).

Answer 82

47% of the world can be classified as dryland. Especially prevalent between the Tropics.

Answer 83

- Decreased plant density. - Reduction in plant height, affecting hydraulic conductance. - Multi-stemmed plants to avoid cavitation. - Shedding twigs or segmentation to prevent cavitation. - Increase in solute potential.

Answer 84

Water Tapping: Plants tap into groundwater reserves. Phreatophytes: Plants like Boscia with deep roots (e.g., 68m underground in the Kalahari desert).

Answer 85

Occurs at night when transpiration is suppressed. - Water moves from groundwater storage into roots and up the plant. - Soil is recharged as water moves out at night due to lower water potential in the soil - During the day, transpiration occurs and water potential is lower in roots, so water moves back into the plant

Answer 86

Stable Isotopes: Changes in heavy and light O and H concentrations. - Markers: Compared with the Standard Mean Oceanic Water (SMOW) (δ). - Experiment: Water enriched with a heavy isotope, with evaporation revealing differences in isotopic composition based on temperature. As lighter is evaporated before

Answer 87

Drought Avoidance: Succulents store water to take advantage of short rain events. Root Sensitivity: Roots are sensitive to soil water deficit. Cortex Shrinkage: Cortex shrinks to isolate tissue. Protection: Protect mature roots by cavitating new roots.

Answer 88

Tree mainly used groundwater, tapping. Evidence: Herbaceous Plants Analysis: Gradient in isotope ratio, plants closer to Acer saccharum used groundwater from hydraulic lift. So water is used by surrounding plants by soil being recharged

Answer 89

Rate of breakdown controlled by diurnal cycles - Altered by day and night length - Important to ensure store doesn't run out over night

Answer 90

Layers of soil influenced by bedrock and weathering. Breakdown of organic matter contributes to humic content - Soil is negatively charged, binding to cations. - Influenced by size, pH, and humic content. - Larger particles have greater CEC.

Answer 91

Macronutrients: Required in high concentration (e.g., N, P, K). Micronutrients: Required in small amounts (e.g., Fe, Boron). K+, Ca2+, Mn, Mg2+: Osmotic relations, signaling, cofactors. Fe, Zn, Cu: Redox reactions.

Answer 92

Too low: Deficiency (e.g., Ca2+ cork spot). Perfect: Adequate zone. Too high: Toxicity (e.g., leaf tip necrosis in barley). Critical Concentration at 10% reduction in growth, past that leads to rapid recline

Answer 93

Adequate zones vary between species. - Avenella (common in deficient soils) grows well at low phosphate concentrations. - Urtica (nettle) grows better at increasing concentrations, while Avenella saturates early.

Answer 94

Apoplastic Flow: - Travels in the aqueous phase. - Blocked by exodermis. Symplastic Flow: - Travels in cells via plasmodesmata. - Not blocked by endodermis. Coupled-Transcellular Pathway: - Influx and efflux protein transporters. - Movement in and out of cells.

Answer 95

ABA promotes deposition of suberin, Ethylene promotes suberin removal. - Suberinization (deposition of suberin) is hormonally controlled. Endodermis: Contains Casparian strip and suberin lamellae.

Answer 96

LATS: channels, present at high concentrations HATS: Antiporters and symporters, activated when concentrations are low

Answer 97

1. Ribosome Function: Crucial for ribosome activity. 2. Metabolism (Pyruvate Kinase): Involved in metabolic processes. 3. Osmotic Relations: Plays a role in maintaining osmotic balance. Deficiency: Leads to increased vulnerability to infections.

Answer 98

High Soil [K+]: - Passive movement into root epidermis. - Active movement into the vacuole. Low Soil [K+]: - Active movement into root epidermis. - Active movement out of the vacuole into the cytosol.

Answer 99

Sets pH gradient, used for secondary active transport. Functional Domains: N = binds to ATP. R = regulatory, phosphorylation leads to activation and 14-3-3 protein binding.

Answer 100

Active transporter. Allows movement of K+. Negative charge also transports Caesium. ~During low concentrations, demonstrated by experiments with Rb+ (a K+ tracer) and changes in pH.

Answer 101

- Inward rectifier channel. - Passes K+ better inward than outward. Experiment: Patch clamp electrophysiology.

Answer 102

SKOR (Stelar K Outward Rectifier): - Atskor mutant shows reduced K+ accumulation in the shoot. - Promotes unloading into sink tissues - Promotes loading into the xylem

Answer 103

Critical for osmotic relations. - Involves H+ ATPase, NHX1/2 antiporters, and V-PPase. - Graphs illustrate differences in vacuolar K+ content between WT and mutants.

Answer 104

- Activated by Ca2+ and 14-3-3 proteins. - Acts as a dimer on the tonoplast. - Not able to release during K+ starvation. ~~ Involved in the release of potassium from vacuoles

Answer 105

Triggers: Ethylene production inhibits elongation and triggers HAK5. Low K+: - Increased suberin deposition in the endodermis. - Downregulation of SKOR (less xylem unloading). - ABA responses.

Answer 106

Amino Acids: Fundamental building blocks of proteins. Nucleotides: Key components of DNA and RNA. Secondary Metabolites: Various compounds contributing to plant physiology.

Answer 107

- Stunted Growth: Impaired overall plant development. - Decreased Photosynthetic Capacity: Reduction in the ability to perform photosynthesis. -Chlorosis: Yellowing of leaves due to insufficient chlorophyll. - Poor Grain Quality: Affects the quality of harvested grains.

Answer 108

Nitrogen to Nitrate: Nitrogenase, found in diazotrophs like Rhizobia and Cyanobacteria. Examples: Rhizobia (legumes) and Cyanobacteria are bacteria involved in nitrogen fixation. - Or via nitroplast Coale et al., 2024

Answer 109

Acidic (ammonium, amino acids), Higher pH (nitrate) Arctic soils (amino acids) Nitrate Transporters: NRT1 (Low affinity), NRT2 (High affinity). Ammonium Uptake: Involves AMT family (HAT and LAT). Amino Acid and Urea Uptake: Mediated by specific transporters.

Answer 110

Nitrate → Nitrite: - Nitrate Reductase: Transfers electrons from NADPH or NADH. - Components: FAD, Cytochrome b557, Molybdopterin. Nitrite → Ammonium: - Nitrite Reductase: Contains Fe-S clusters and Siroheme, found in plastids.

Answer 111

Glutamine Synthetase (GS): Converts ammonium and glutamate to glutamine. GOGAT: Transaminase enzymes facilitate the transfer of amine (NH2) to an oxo acid. Regeneration: Allows glutamate to be regenerated for reincorporation into the cycle. ~~Crucial for incorporating nitrogen into amino acids in plants.

Answer 112

Short Term Storage: - Excess stored in vacuole via H+/NO3- antiporter. Medium Term Storage: - Protein and non-protein amino acids like Asparagine and Canavanine. Long Term Storage: - High molecular weight proteins (e.g., Globulins in legumes, Prolamins in cereals).

Answer 113

Break down into amino acids and nitrate. Annual Plants: Up to 90% of nitrogen remobilized to seeds, controlled by NRT1 and NRT2.

Answer 114

GS in Cytosol: Captures ammonium from remobilization. GS in Chloroplast: Captures ammonium released during photorespiration. Reassimilation involves capturing released ammonium and incorporating it back into nitrogen metabolism.

Answer 115

- Importance for Nitrogen Fixation: Carbon skeletons crucial for nitrogen fixation. - Rubisco and Nitrogen: Nitrogen essential for Rubisco activity, required for carbon fixation. - Loss of Nitrogen: Occurs during photorespiration.

Answer 116

Adv- Increases yield, averts hunger crisis Diasdv- environmental pollution, energy intensive (Harber-process)

Answer 117

- Energy Stores: Found in ADP and ATP molecules. - Phospholipids: Constituent of cell membranes. - Nucleic Acids: Essential for the structure of RNA and DNA. - Protein Regulation: Involves phosphorylation of enzymes and transporters.

Answer 118

Phytate in Seeds: Storage form of phosphorus in seeds. Polyphosphates in Vacuole: Another form of phosphorus storage in the vacuole.

Answer 119

Low Metabolism: Leads to stunted growth. Chlorosis: Results in yellowing of leaves. Sulpholipids: Substituted for phospholipids in membranes. Poor Frost Resistance: Impaired ability to withstand frost.

Answer 120

Phosphorus is mobilized in the form of phosphate anions during nutrient redistribution.

Answer 121

1. Binding Elements: Phosphorus is bound to iron, aluminum, and calcium in soils. 2. Optimal pH: Neutral pH enhances phosphorus availability.

Answer 122

Microbial Activity: Microbes secrete phosphatase to release phosphate. NPK Fertilizer: Although harmful to the environment, it can increase phosphorus availability.

Answer 123

1. Mycorrhizal Symbiosis: Aims to move out of the depletion zone created by roots. 2. Root Architecture Changes (Cluster Roots): Formation of cluster roots, controlled by auxin patterning. 3. Root Architecture Changes (Basal Roots): Increase in basal roots to move out of the depletion zone.

Answer 124

1. Sensing: LPR multicopper oxidases in the root cap ER are involved in sensing low phosphorus levels causes Fe- mediated ROS production 2. Response: - Involves cessation of root growth - increased lateral root production - Malate secretion - Callose deposition. 3. Signaling: Auxin plays a role in changing root structure in response to phosphorus levels.

Answer 125

1. Master Regulator: PHR1 (Phosphate Starvation Response): - Upregulates high-affinity Pi symporters (Pht1 and Pht4). 2. High Affinity H+ Symporters (Pht1 and Pht4): - Found on root hair cells and secrete H+ to increase soil acidity. 3. Transport of Transporters to Membrane (PHF1): - Facilitates the transport of Pht1 and Pht4 to the plasma membrane from the ER. 4. Xylem Loading (Aided by PHO1): - PHO2 is a negative regulator suppressed by PHR1 via microRNAs.

Answer 126

- Transporters (VPE1 and VPE2) found in rice - Double mutant leads to greater conc of Pi in vacuole - Increase in expression of transporters in Pi deficiency (Xu et al., 2019)

Answer 127

Cytokinin and Phosphate Signaling Reduction in Shoots Stimulates changes in root architecture and nutrient uptake.

Answer 128

Essential for photosynthesis, respiration, and cell membrane structure. Assimilation: SO4²- is taken up via H+ symporters, assimilated into cysteine, and stored as glutathione. Can also replace Phosphate when Pi levels are low to form sulpholipids

Answer 129

1. Efficient Electron Acceptor: Iron efficiently accepts electrons in various cellular processes. 2. Enzyme Cofactor: Serves as a crucial cofactor for enzymes involved in respiration and photosynthesis. 3. Haem and Fe-S Clusters: Iron is stored in haem (siroheme) and Fe-S clusters, primarily in chloroplasts. 4. Fenton Catalyst: In its free form, iron acts as a Fenton catalyst, catalyzing the production of hydroxyl radicals.

Answer 130

Ferretin (Seeds): Captures iron to prevent cytosolic toxicity, predominantly located in plastids. Vacuole: Iron is stored and loaded into the vacuole by VIT1 and FPN2 transporters. Apoplast: Iron is also stored in the apoplast, bound to pectin. Chelation: Chelated to form phytate and stored in seeds of cereals.

Answer 131

Chlorophyll Synthesis Inhibition: Impairs the synthesis of chlorophyll. Stunted Growth: Results in overall growth inhibition. Nitrogen Assimilation Impairment: Affects nitrogen assimilation processes. Vein Chlorosis: Leads to yellowing of leaf veins.

Answer 132

Optimal pH: Around 6.5 for iron availability. Rhizosphere Acidification: Root H+ ATPases secrete H+ to acidify the rhizosphere, enhancing iron solubility.

Answer 133

1. Rhizosphere Acidification (AHA2): Root H+ ATPases secrete H+ to acidify the rhizosphere. 2. Iron Solubilization: This acidification solubilizes Fe3+ in the soil. 3. Phenolic Chelators: Phenolic chelators are secreted to bind to iron. 4. Ferric Chelate Reduction (FRO2): Membrane-bound Fe3 reductases reduce ferric chelate. 5. Iron Uptake (IRT1): Fe2+ is transported into the cytosol. Connorton et al., 2017

Answer 134

1. Chelator Secretion(TOM1): Grasses secrete chelators like Nicotianamine (NA) to capture Fe3+ 2. Specific Transporters (YS1): Fe3+ is taken up by specific transporters like - Take up (Fe+) can also be via IRT1 directly - Or apoplastically through the Casparian strip in Fe deficiency Connorton et al., 2017

Answer 135

- Xylem Transport: Chelated to citrate for transport into the xylem. - Chloroplast Uptake: Utilizes the CIP1 permease for incorporation into chloroplasts. - Plastids: Involved in the incorporation of iron into haem and Fe-S clusters, e.g., ferredoxin.

Answer 136

ABA signalling (stress) 1. Vacuole - In VIT1 - Out NRAMP3/4 2. Ferritin degradation = Bound to Nicotianamine (NA) when in Fe2+ state in symplast

Answer 137

Balancing S and Fe: Required for forming Fe-S clusters. Fe and S Interplay: High Fe induces S efflux via SULTR transporters; low S decreases Fe uptake by Ferretin. ABA Role: ABA alleviates chlorosis by promoting Fe uptake

Answer 138

Essential for wall integrity and rigidity, binding to pectins. Uptake: As H(BO)3, via NIP channels; transported through Casparian strip via BOR transporters.

Answer 139

Deficiency: Leads to stunted growth and male sterility, upregulates transporters. Toxicity: Causes leaf necrosis and root growth inhibition, involves ubiquitination for transporter endocytosis.

Answer 140

Sahara Barley: Shows greater boron efflux from roots and less in shoots, indicating efficient transporter (BOT1) activity. Clipper Barley: Accumulates more boron in leaf blades, potentially reaching toxic levels and inhibiting growth.

Answer 141

BOT1 Efficiency: Sahara BOT1 is a more efficient transporter than Clipper BOT1, differing in only 2 amino acids. QTL analysis reveals the genetic basis of boron uptake efficiency and its impact on plant tolerance.

Answer 142

- Threat to Food Security: Results in an average annual loss of $123 billion, impacting 1/3 of global food production on irrigated land. - Yield Reduction: A 40% reduction in water availability leads to a 20-30% reduction in wheat and maize yields.

Answer 143

- Inhibition of Photosynthesis: Due to stomatal closure. - Increase in ROS: Resulting from decreased photosynthesis. - Cellular Damage: Caused by reactive oxygen species (ROS). - Reduced Growth: Due to lower water potentials. - Reduced Nutrient Uptake: Resulting from reduced transpiration efficiency.

Answer 144

- Drought Escape: Involves early maturity, rapid plant development, and seasonal growth. - Drought Avoidance: Aims to maintain optimal water content through mechanisms like stomatal closure and changing leaf structure. - Drought Tolerance: Focuses on minimizing damage, utilizing strategies like osmotic adjustment and antioxidant defense mechanisms.

Answer 145

- Early Maturity: Accelerated plant maturation. - Rapid Plant Development: Swift growth to complete the life cycle quickly. - Seasonal Growth: Adaptation of growth patterns to specific seasons.

Answer 146

- Minimize Water Loss: Achieved through stomatal closure (reduced transpiration) and leaf rolling. - Changing Leaf Structure: Structural modifications to reduce water loss. - Increased Water Uptake: Enhanced water uptake from roots, often involving deeper primary roots and minimal lateral roots.

Answer 147

- Osmotic Adjustment: Inclusion of compatible solutes in roots to lower water potential and drive water uptake. - Compatible Solute Examples: Mannitol, proline, glycine. - Antioxidant Defense Mechanisms: Utilization of carotenoids, ROS-detoxifying enzymes, and Late Embryo Abundant (LEA) proteins.

Answer 148

Arbuscular Mycorrhizal Fungi: Form symbiotic relationships with plants. Evidence: Confocal microscopy analyzes the location of fungi. Benefits: Bring phosphate and nitrogen to the plant in exchange for carbon.

Answer 149

- Osmotic Sensing: Changes in concentrations lead to conformational changes in receptors like histidine kinase. - Mechanosensitive Channel: Turgor pressure changes activate mechanosensitive channels like calcium-permeable channel (OSCA1). - Cell Wall Integrity: Changes in turgor pressure affect cell wall integrity, triggering responses like protein detachment (e.g., CrLK).

Answer 150

Increase in ABA: Leads to stomatal closure. Plastid Release: ABA is released from plastids in the roots. Guard Cell Action: Acts on guard cells to regulate stomatal aperture.

Answer 151

Enhancer Binding: Binding to enhancers increases transcription of proteins related to drought tolerance. Example: DREB (Drought Responsive Element-Binding) is a transcription factor involved.

Answer 152

Sahbhagi Dhan (SD) Rice: - Developed through conventional breeding, altering flowering times to avoid drought. Kindandan Patong (KP) Rice: - Develops deeper roots with a greater root angle to enhance water uptake. - Changes are attributed to different expression of DRO1 (Deep Root1).

Answer 153

Flooding: An area covered with excess water, impacting plant growth. Food Security: Flooding accounts for 9% of overall hazards, reducing nutrient availability and posing a threat to food production.

Answer 154

Reduced Diffusion Rates: Hindered movement of gases and nutrients. - Reduced CO2 Levels: Leads to decreased photosynthesis. - Reduced O2 Levels: Result in a lack of anaerobic respiration, causing anoxia.

Answer 155

Escape: Altering the timing of the growth cycle, such as flowering before flooding. Avoidance: Involves adaptations in root development, shoot development, and metabolic adjustments. Tolerance: Includes metabolic adjustments, fermentation, and the use of antioxidants to counteract damage from reactive oxygen species (ROS).

Answer 156

Sensing Oxygen Levels: Leads to the accumulation of ethylene - lack of oxidation of cysteine on ERF- VII - lack of arginine addition - No ubiquitination by E3 ligase Increase Ethylene: increases GA

Answer 157

Transcription Factor: Ethylene responsive factor group VII (ERF-VII). Regulation: Under normal oxygen conditions, ERF-VII is degraded by plant cysteine oxidases (PCO).

Answer 158

Ethylene: A gaseous hormone promoting fruit ripening; its diffusion is reduced during flooding. Gibberellins: Promote cell elongation, contributing to shoot development.

Answer 159

Deep-water Rice (Escape): - Rapidly elongating stems, activated by ethylene. - Ideal for long-term steadily rising flood climates. - Increased gene expression of SD1 and Snorkel 1/2 in deepwater rice

Answer 160

- SUB1 is activated, triggering DELLA, inhibiting elongation. - Ideal for short-term (14days) climate changes like flash flooding

Answer 161

DELLA: Binds the transcription factor that promotes elongation. - GA binds to DELLA, leading to its degradation.

Answer 162

Secretion of anti-oxidants

Answer 163

- pH correlates to the concentration of H+ - A H+ gradient is important in the functioning of ATPsynthase - Requires a greater concentration of H+ in the thylakoid lumen, which then moves to the stroma of the chloroplast - H+ is also required to activate PsbS to trigger NPQ when excess light hits the cell

Answer 164

-Different transporters for different affinities, different conc such as HAK5 and AKT1 - Many minerals are required and they can have different charges and be of different sizes, Phosphate, Nitrate, K+, etc. - Expression on different membranes as part of uptake and storage, e.g. transporters on the tonoplast are different to transporters on the cell membrane - Greater family allows for greater diversity and ability to adapt

Answer 165

- Sclerophyllous leaves (thick and leathery) = against desiccation - Small leaves - reduce water loss - Succelence - store water in stem - Leaf rolling - prevent transpiration - Aromatic compounds to protect the plant from excess light

Answer 166

- Low and high concentrations, varying high and low affinity transporters - Encode for H+ ATPases as well, that drive secondary active transport - NRT1 = low affinity, and NRT2 = high affinity - Can transport different forms of nitrogen compounds, nitrate, ammonium, urea, peptides etc.

Answer 167

- Alter Fe as a main use of Fe is in Fe-S clusters - So matching of content needs to be generated - Achieved by regulating siderophore production - Changes to root architecture to match S conc

Answer 168

Deplete soils HAK5 - high affinity uptake, coupled with H+ Replete soils AKT1 - low affinity uptake - Movement symplastic (cytoplasm) or apopastically SKOR - outward rectifying channels that move K+ into the xylem

Answer 169

- Sequester into vacuoles to reduce toxicity e.g. via BOR1 transporters - Selective transporter to block uptake

Answer 170

1. Shrunken maize- reduced starch synthesis led to small, wrinkled kernels 2. Sucrose mutants- reduced production of starch, because of knock on reduction in fructose and UDP-G 3. Starch synthase mutant - build up of ADPG, but no starch

Answer 171

Pigments - Land plants use cholorophyll - Bacteria use bacteriochlorophyll, bacteriorhodopsin and bilins (cyano) Source of e- - Land plants (H2O) - Many bacteria (H2S), or cyano (H2O) Photosystems - Land plants PSI and PSII - Bacteria mainly one PS that harvest light e.g. GSB and purple, except cyano

Answer 172

1. Protonation of PsbS regulates NPQ activation 2. Regulates activity of enzymes in Xanthophyll cycle - de-epoxidases (VDE) for zeaxanthin 3. Signals stress as pH gradient is present in ETC

Answer 173

Hydraulic conductance - Measure of ease of water movement - Higher = more drought tolerant - Maintain turgor pressure Water potential - Used to locate source of water - Drought tolerant able to maintain, to drive water movement

Answer 174

- Measurement to quantify heat accumulation and the effect on development - Used to predicting effect on germination, flowering etc. - Monitoring the effects of climate change - Comparative analysis for different regions or years

Answer 175

* OR – origin replication * OriT – origin for T-DNA transfer * Vir region – facilitates transfer of T-DNA into the plant, via T4SS * T-DNA section that is inserted, which causes pathology * Selectable markers – ensure and check that transformation has occurred

Answer 176

- H+ ions among others - Rubisco enzymes - Ribosomes - Chloroplast genome - mRNA - Starch granules

Answer 177

1. Post-translational - Phoshorylation leads to inactivation 2. Allosteric Pi - inhibitory G6P - activator 3. Coregulation - due to complementation of proteins 4. Hormonal - Cytokining promote, ABA supress

Answer 178

1. Hydraulic lift - Deep roots to tap into groundwater sources and maintain flow of water 2. Tracheids (gymnosperms) - Narrow to prevent risk of cavitation - Bordered pits to prevent runaway cavitation, by allowing them to be sealed off 3. Osmotic adjustment - Control the production of solutes to ensure efficient and consistent water flow occurs

Answer 179

Water potential - Lower better, can drive more water in from drier soils - Due to osmotic adjustment Hydraulic conductance - Higher means easier water movement - Increases risk of cavitation

Answer 180

Cavitation- Water flow is blocked due to an air embolism Repair - Increase in compatible solutes, lowers water potential - Xylem formation - Lignin deposition (prevent) - Hydraulic segmentation to prevent spread

Answer 181

- Thick cuticle - High lignin content (leathery) - Few stomata - Higher water use efficiency (WUE)

Answer 182

- Low water use efficiency - Soft thin, larger leaves - Abundant mesophyll cells for photosynthesis

Answer 183

DRY - Caused by increased tension which increases air bubble formation - Adapt by hydraulic segregation and deeper roots COLD - Freeze-thaw embolisation, due to freezing and melting forming air bubbles - Narrow vessels and anti-freeze proteins

Answer 184

NHX1 (tonoplast) - Na+ moved in in exchange for H+ SOS1 (plasma membrane) - Antiporter moves Na+ out HKT1 (plasma membrane) - HA transporter moving Na+ in

Answer 185

Amylose - 1,4 glycosidic bonds - Coiled structure - Long term store Amylopectin - 1,6 and 1,4 glycosidic bonds - More soluble - Branched structure - Readily accessible

Answer 186

Genetic evidence - Mutants led to reduced starch, increase in ADPG - Overexpression led to greater starch Enzymatic activity - Detected in tissues that are producing starch

Answer 187

Catalyses formation of 1,6 glycosidic bonds for amylopectin Discovery - Mutants and sequencing via PCR to identify changes

Answer 188

1. Electron microscopy 2. Genetic (mutants) - defects in fatty acid metabolism 3. Biochemical isolation - isolate enzymes involved in the cycle (MS and IL)

Answer 189

Fine - Rapid, reversible modifications e.g. allosteric or Pi - Regulation of PFK allosterically by ATP and citrate Coarse- Change in enzyme conc through expression and synthesis - porin expression OmpC and OmpF, in differing concentrations

Answer 190

1. Limiting factors - Other limiting factors such as RuBP regeneration - Rate of Rubisco 2. Acclimation - Downregulate to counteract initial stimulation 3. Feedback inhibition - No increase in demand so no increase in production - Avoid large accumulation of solutes

Answer 191

Cav1 mutant - unable to move chloroplast in response to high blue light - Microscopy can be used to localise the chloroplasts Importance - Prevent photodamage - Optimise photosynthetic efficiency e.g. during shading

Answer 192

1. Location Land plants located in chloroplasts that specialised organelles Bacteria located on the plasma cell membrane 2. Pigment Land plants - use chlorophyll Bacteria - use bilins, bacteriochlorophyll and bacteriorhodopsin 3. Photosynthetic systems (PS) Land = have PSII and PSI Bacteria = Cyano has both, purple has PSII similarity and GSB has PSI similarity 4. Source of e- Land = water to produce oxygen Bacteria = H2S mainly, except Cyano

Answer 193

Reaction centre with D1 and D2 proteins Light harvesting around (containing pigments) 1. Become excited 2. Able to pass on excited to the P680 in the RC 3. E- transfer in ETC 4. energy released when e- transferred drives movement of protons for ATP synthesis

Answer 194

1. Light harvesting 2. Photoprotection - inefficient energy transfer 3. Precursor to hormones 4. Antioxidant activity

Answer 195

Adv - Other form of energy store - More efficient store, higher energy content per gram - Require less water for storage - Good long term store Disadv - Requires specific enzymes - Complex metabolism pathway

Answer 196

Redox of the disulphide bond by ferredoxin - Light = reduction = no S-S = active and vice versa

Answer 197

1. Triose C usage - Decrease in sucrose synthesis leads to increase in starch synthesis 2. Sucrose conc - Used to form storage starch 3. Pi changes - Release of Pi from Sucrose, alters 3PGA:Pi which alters rate of ADPG PPiase 4. Diurnal cycles - Starch breakdown at night to form sucrose, sucrose formed throughout

Answer 198

1. SPS - Pi of Serine158 leads to inactivation 2. F-2,6-BPase - Increase in Pi leads to inactivation 3. AGP-ase - Increase leads to decrease in production of ADPG 4. PHF1 - Decrease in Pi, promotes its action of transporting transporters to the membrane 5. Ph transporters - Deficiency leads to increase in HAT (Pht1 and Pht4)

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