Biology Plant Biology

Key Concepts & Formulas

Provide 5-7 essential concepts for Biology Plant Biology:

10 Practice MCQs

Q1. Which part of the plant contains chloroplasts for photosynthesis? A) Root hairs B) Leaf mesophyll cells C) Xylem vessels D) Root cortex cells

Answer: B) Leaf mesophyll cells

Solution:

• Chloroplasts are concentrated in palisade mesophyll cells (50-100 per cell)
• These cells are positioned just below upper epidermis for maximum light absorption
• Root cells lack chloroplasts as they don’t receive light underground

Shortcut: “Chloroplasts need light → find cells that receive most light → upper leaf surface”

Concept: Biology Plant Biology - Photosynthesis location

Q2. The process where water moves from roots to leaves against gravity is called: A) Transpiration B) Guttation C) Osmosis D) Root pressure

Answer: A) Transpiration

Solution:

• Transpiration creates pull (transpiration pull) from leaf surface
• Cohesion-tension theory: water molecules stick together (cohesion) and are pulled upward
• Rate: 15-45 m/hour in tall trees

Shortcut: “Transpiration = Transportation upward; starts with ‘T’ = ‘Top’ pull”

Concept: Biology Plant Biology - Water transport mechanism

Q3. Which hormone causes seed dormancy? A) Auxin B) Gibberellin C) Abscisic acid D) Cytokinin

Answer: C) Abscisic acid

Solution:

• Abscisic acid (ABA) concentration: 10-50 μg/g dry weight in dormant seeds
• Prevents premature germination; breaks down with water/scarification
• Also causes stomatal closure during drought

Shortcut: “ABA = Anti-Breaking-Active; stops germination”

Concept: Biology Plant Biology - Plant hormones

Q4. A plant loses 50g water in 5 hours through transpiration. If leaf surface area is 100 cm², calculate transpiration rate per cm²/hour. A) 0.1 g/cm²/hr B) 0.5 g/cm²/hr C) 1.0 g/cm²/hr D) 2.5 g/cm²/hr

Answer: A) 0.1 g/cm²/hr

Solution:

• Total transpiration = 50g/5 hours = 10g/hour
• Rate per cm² = 10g/hour ÷ 100 cm² = 0.1 g/cm²/hour
• Normal range: 0.05-0.2 g/cm²/hour for most plants

Shortcut: “Divide total by both time and area: 50÷5÷100 = 0.1”

Concept: Biology Plant Biology - Transpiration calculation

Q5. In a C3 plant, how many ATP molecules are required to fix one CO2 molecule? A) 1 B) 2 C) 3 D) 4

Answer: C) 3

Solution:

• Calvin cycle requires: 3 ATP + 2 NADPH per CO2
• Breakdown: 2 ATP for phosphorylation, 1 ATP for regeneration
• Total for glucose (6CO2): 18 ATP + 12 NADPH

Shortcut: “3 ATP = ‘Tri’carbon fixation needs ’tri’ ATP”

Concept: Biology Plant Biology - Photosynthesis energy requirements

Q6. A station gardener observes guttation drops on grass at 5 AM. This occurs through: A) Stomata B) Lenticels C) Hydathodes D) Cuticle

Answer: C) Hydathodes

Solution:

• Guttation: water droplets from leaf margins (100-200 droplets/cm²)
• Occurs when transpiration is low (high humidity, night) and root pressure is high
• Hydathodes present at vein endings in grass (200-500 per leaf)

Shortcut: “Gutta-tion = Gutter-like drops → need special ‘holes’ = Hydathodes”

Concept: Biology Plant Biology - Water loss mechanisms

Q7. If a train’s pantry car stores 500 kg potatoes, how much CO2 do they release daily through respiration at 25°C? (Assume 1 kg potatoes release 0.4g CO₂/day) A) 100g B) 200g C) 400g D) 500g

Answer: B) 200g

Solution:

• CO₂ release = 500 kg × 0.4g/kg = 200g/day
• Respiration rate doubles every 10°C rise (Q10=2)
• At 25°C, rate is 2.5× faster than at 5°C

Shortcut: “500 × 0.4 = move decimal: 50 × 4 = 200”

Concept: Biology Plant Biology - Plant respiration rates

Q8. A 20m railway platform tree shows annual rings: 12 rings in 6cm radius. Calculate average yearly radial growth. A) 0.25 cm/year B) 0.5 cm/year C) 1 cm/year D) 2 cm/year

Answer: B) 0.5 cm/year

Solution:

• 1 ring = 1 year growth (in temperate climates)
• Total growth = 6 cm over 12 years
• Average = 6 cm ÷ 12 years = 0.5 cm/year
• Secondary growth occurs in vascular cambium

Shortcut: “Growth per year = total ÷ rings: 6÷12 = 0.5”

Concept: Biology Plant Biology - Secondary growth calculation

Q9. In a greenhouse at 30°C, C3 plant photosynthesis rate is 15 mg CO₂/dm²/hour. If temperature drops to 20°C, what’s the new rate? (Q10 for photosynthesis = 2) A) 3.75 mg B) 7.5 mg C) 30 mg D) 60 mg

Answer: B) 7.5 mg

Solution:

• Temperature coefficient Q10 = 2 means rate halves every 10°C drop
• 30°C → 20°C = 10°C drop
• New rate = 15 ÷ 2 = 7.5 mg CO₂/dm²/hour

Shortcut: “Q10=2: every 10°C drop = half rate”

Concept: Biology Plant Biology - Temperature effects on photosynthesis

Q10. A train carries 1000 quintals wheat. If 2% by weight is lost to respiration during 10-day journey at 35°C, calculate total CO₂ produced. (Respiratory quotient = 1, wheat CHO composition) A) 2 quintals B) 20 quintals C) 200 kg D) 2000 kg

Answer: A) 2 quintals

Solution:

• 2% of 1000 quintals = 0.02 × 1000 = 20 quintals wheat lost
• RQ = 1: 1g CHO → 1g CO₂ produced
• CO₂ produced = 20 quintals = 2 metric tons

Shortcut: “2% loss = 2% CO₂ produced from original”

Concept: Biology Plant Biology - Respiratory losses calculation

5 Previous Year Questions

PYQ 1. The green pigment essential for photosynthesis is: [RRB NTPC 2021 CBT-1]

Answer: Chlorophyll

Solution:

• Chlorophyll a: C₅₅H₇₂MgN₄O₅ (primary pigment)
• Absorbs red (660nm) and blue-violet (430nm) light
• 1g chlorophyll can fix 100g CO₂/hour in optimal conditions

Exam Tip: Remember “Chloro” = green, “phyll” = leaf; always associated with light reactions

PYQ 2. Which tissue transports food from leaves to roots? [RRB Group D 2022]

Answer: Phloem

Solution:

• Phloem sap velocity: 0.3-1.5 m/hour
• Transports sucrose (10-30% concentration)
• Companion cells provide energy for active transport
• Direction: source (leaves) → sink (roots/storage)

Exam Tip: “Phloem = Food transport; flows ‘down’ but can go up to fruits”

PYQ 3. Calculate water potential if solute potential = -8 bars and pressure potential = +3 bars. [RRB ALP 2018]

Answer: -5 bars

Solution:

• Water potential (Ψ) = Solute potential (Ψs) + Pressure potential (Ψp)
• Ψ = -8 bars + 3 bars = -5 bars
• Negative indicates water will move in (higher to lower potential)

Exam Tip: Always add: solute (usually negative) + pressure (usually positive)

PYQ 4. A station nursery has 200 plants. If each plant transpires 500ml/day, calculate total water loss per week. [RRB JE 2019]

Answer: 700 liters

Solution:

• Daily loss = 200 × 500ml = 100,000ml = 100 liters
• Weekly loss = 100 × 7 = 700 liters
• Average mature plant: 200-1000ml/day depending on species

Exam Tip: Convert ml to liters at end: 1000ml = 1 liter

PYQ 5. Which mineral deficiency causes yellowing between leaf veins? [RPF SI 2019]

Answer: Iron

Solution:

• Iron deficiency: Interveinal chlorosis (green veins, yellow tissue)
• Iron needed for chlorophyll synthesis (0.1-0.5% dry weight)
• Common in alkaline soils (pH >7) where iron becomes unavailable

Exam Tip: “Iron = Interveinal symptoms; Magnesium = Overall yellowing”

Speed Tricks & Shortcuts

For Biology Plant Biology, provide exam-tested shortcuts:

Common Mistakes to Avoid

Quick Revision Flashcards

Topic Connections

How Biology Plant Biology connects to other RRB exam topics:

• Direct Link: Chemistry - Photosynthesis involves redox reactions (CO₂ reduction, H₂O oxidation)
• Combined Questions: Physics - Light absorption spectra, pressure calculations in xylem
• Foundation For: Environmental Science - Carbon cycle, oxygen production, deforestation impacts
• Math Applications: Calculating growth rates, transpiration ratios, photosynthetic efficiency
• Current Affairs: GM crops, organic farming, carbon sequestration by railways