The big idea: Before a cell divides it must make an exact copy of all its DNA. This copying is called DNA replication.
DNA replication is semi-conservative. The double helix unzips into its two strands, and each old strand acts as a template for building a new partner strand.
The result is two identical molecules, and each one keeps one old (parental) strand paired with one new strand. 'Semi' = half: half of each new molecule is conserved from the original.
Helicase unzips the double helix and DNA polymerase builds a new complementary strand on each template, so each daughter molecule keeps one old (parental) strand and one new strand — this is what 'semi-conservative' means.
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- DNA replication
- The process of copying a DNA molecule to produce two identical molecules, carried out before a cell divides.
- Semi-conservative replication
- Replication in which each new DNA molecule is made of one original (parental) strand and one newly built strand.
- Template strand
- An old strand of DNA that is used as a pattern to build a new complementary strand.
- Complementary base pairing
- The rule that adenine pairs with thymine (A–T) and cytosine pairs with guanine (C–G), so each template strand specifies exactly one possible new strand.
- Daughter molecule
- One of the two identical DNA molecules produced by replication.
Why each copy keeps an old strand: Because the two strands are held together by complementary base pairing, an old strand already carries all the information needed to rebuild its partner.
So replication does not throw the old strands away — it keeps each one and builds a fresh partner against it. That is exactly why every new molecule ends up half old, half new.
To see why the copying is semi-conservative, follow the strands through one round of replication.
The key is that the two parental strands are separated but never destroyed — each one is kept and used as a template.
One round of replication, step by step
- The double helix is unzipped, separating the two parental strands.
- Each parental strand acts as a template.
- New nucleotides line up by complementary base pairing (A–T, C–G) against each template.
- The new nucleotides are joined into a continuous new strand.
- Each old strand now sits paired with its own new strand → two identical daughter molecules.
Cause → effect: Cause: the strands separate, and each old strand is copied by complementary base pairing.
Effect: every daughter molecule contains one conserved old strand and one new strand — never two old strands together and never two new strands together.
Conservative (what does NOT happen)
- Both old strands stay in one molecule
- Both new strands go into the other molecule
- One molecule is all old, one is all new
- This was ruled out by the evidence
Semi-conservative (what DOES happen)
- The two old strands are separated
- A new strand is built onto each old strand
- Each molecule = one old + one new strand
- This is the model the evidence supports
| Feature | Conservative (rejected) | Semi-conservative (correct) |
|---|---|---|
| Old strands | Both stay together in one molecule | Split up — one goes to each daughter molecule |
| New strands | Both built into the other molecule | One built onto each old template strand |
| Each daughter molecule | Either all-old or all-new | One old strand + one new strand |
| Generation-1 band | Would be one heavy + one light band | One intermediate band (what was actually seen) |
Three possible models: Before the experiment, three models were possible:
Conservative — the whole old molecule is kept and a whole new one is made separately.
Semi-conservative — each new molecule is one old strand + one new strand.
Dispersive — each strand is a patchwork of old and new pieces.
The next section is the experiment that decided between them.
A memory hook: 'Semi' = half. Each copy keeps half of the original — one old strand. If you remember 'half old, half new', you remember the whole model.
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How this is tested: The Meselson-Stahl experiment is a classic data-reasoning question. Bacteria are first grown with the heavy nitrogen isotope ¹⁵N so all their DNA is heavy, then switched to light ¹⁴N, and the DNA from each generation is spun in a centrifuge to sort it by density.
On Paper 2 a 2-mark Explain question asks you to read the banding pattern and say what it shows, then a 1-mark State asks for the conclusion (replication is semi-conservative).
On Paper 1A you may simply have to choose the diagram that correctly shows semi-conservative replication — the one where each daughter molecule has one old and one new strand.
IB-style question — explain the centrifuge banding
Bacteria were grown for many generations in a medium containing only the heavy isotope ¹⁵N, then transferred to a medium containing only the light isotope ¹⁴N. After one round of replication in ¹⁴N, the DNA formed a single band at an intermediate density. After a second round, the DNA formed two bands — one at intermediate density and one at a light density. Explain how these results support semi-conservative replication. [2]
How to score both marks
- Read generation 1. After one round there is only one intermediate band, so every molecule is half-heavy and half-light — one old (¹⁵N) strand paired with one new (¹⁴N) strand. This rules out the conservative model, which would have left a separate heavy band.
- Read generation 2. After a second round there is one intermediate band and one light band, so some molecules are now fully light. This rules out the dispersive model (which would keep all DNA at an intermediate density). Only semi-conservative replication fits both results. (Mark 1: generation-1 intermediate band = one old + one new strand. Mark 2: generation-2 intermediate + light bands fit only the semi-conservative model.)
Final answer
Generation 1 forms a single intermediate band — each molecule has one ¹⁵N (old) and one ¹⁴N (new) strand, ruling out the conservative model. Generation 2 forms an intermediate band and a light band, ruling out the dispersive model. Only semi-conservative replication explains both.
✓ Why this scores full marks: It does the two things a data Explain needs: it describes each band (intermediate; then intermediate + light) and links each one to a model it rules out.
Just writing 'replication is semi-conservative' with no reference to the bands would score the State mark but not the Explain marks.
| Sample | Density of the DNA band | What it tells you |
|---|---|---|
| Parent (grown only in ¹⁵N) | One heavy band | All DNA contains the heavy ¹⁵N isotope |
| Generation 1 (one round in ¹⁴N) | One intermediate band | Every molecule is half-heavy, half-light → no fully heavy DNA left → conservative model is wrong |
| Generation 2 (two rounds in ¹⁴N) | One intermediate band AND one light band | Half the molecules are now fully light → dispersive model is wrong → only semi-conservative fits |