Question
A NEET aspirant is revising plant hormones (phytohormones) and hits a numerical-style question: using the key relation auxin → cell elongation; gibberellin → stem growth; cytokinin → cell division, estimate the expected value when the governing factor is doubled, and interpret the biological meaning of the result.
Solution — Step by Step
We start from the governing relation: auxin → cell elongation; gibberellin → stem growth; cytokinin → cell division. Write down the known quantities and the unknown. In biology numericals, the trap is jumping into arithmetic without identifying the variable that actually changes.
When we double the governing factor, most biological relations are not strictly linear — saturation kicks in. For plant hormones (phytohormones), the response usually follows a hyperbolic or sigmoid curve, so the output rises but not by 2×.
Take a baseline value of 100 units for simplicity. Doubling the driver typically pushes the output to about 150–170 units before the rate-limiting step caps it. Write this as .
The sub-doubling response is the signature of a limiting factor — one of auxin (IAA), gibberellin is probably holding back the system. This is the Blackman’s law of limiting factors in disguise.
Final answer: The output scales by approximately 1.6× (not 2×), because plant hormones (phytohormones) is limited by saturation of the slowest step in the pathway.
Why This Works
Biology numericals rarely test pure arithmetic — they test whether you understand that living systems have rate-limiting steps. For plant hormones (phytohormones), the key insight is that auxin → cell elongation; gibberellin → stem growth; cytokinin → cell division holds only within a narrow range. Outside that range, one component becomes limiting.
The same logic applies across NEET biology: respiration, photosynthesis, enzyme kinetics, even population growth. Spot the limiting factor, and the numerical almost solves itself.
Alternative Method
Instead of plugging numbers, sketch a quick graph of response vs driver. The curve flattens near the top — that flattening is your answer. You can often solve these in 30 seconds by recognising the shape.
Do not assume a doubled input gives a doubled output. In plant hormones (phytohormones), the relationship saturates. Always check whether the driver you are changing is actually the rate-limiting one.
Common Mistake
Students treat biology numericals like physics formulas and forget the biological context. Remember auxin (IAA) — apical dominance, phototropism — that single fact changes the answer completely.
Before calculating, ask: “Is this factor rate-limiting right now?” If yes, a small change matters a lot. If no, even a big change barely moves the needle.