In simple terms
A friendly intro before the formal notes — no formulas yet.
The Blueprint of Life
Nucleic acids (DNA and RNA) are the information molecules of the cell. They are long chains built from repeating units called nucleotides, and the order of just four bases along the chain spells out the instructions for building an organism.
Picture DNA as a twisted rope ladder. The two long side ropes are the sugar-phosphate backbones, giving the ladder its strength. The rungs are pairs of bases meeting in the middle, and each rung is held by weak hydrogen bonds so the ladder can be 'unzipped' down the centre to be read or copied. Crucially, the two ropes run in opposite directions, like two escalators side by side, one going up and one going down.
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Build one nucleotide: a five-carbon (pentose) sugar in the middle, a phosphate group attached to its 5' carbon, and a nitrogenous base attached to its 1' carbon.
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Link many nucleotides into a single strand: the sugar of one joins the phosphate of the next, forming a sugar-phosphate backbone with a direction (a 5' end and a 3' end).
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For DNA, place two such strands side by side running in opposite (antiparallel) directions, and pair the bases across the gap: adenine with thymine, guanine with cytosine.
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Hold the pairs together with hydrogen bonds (two for A-T, three for G-C) and let the whole molecule twist into a double helix. The order of the bases is the stored information.
Explore the concept
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Full topic notes
Formal explanation with the rigour you need for the exam.
The structure of a nucleotide
The monomer (repeating unit) of a nucleic acid is the nucleotide. Each nucleotide has three parts joined together: a pentose (five-carbon) sugar in the centre, a phosphate group attached to the 5' carbon of that sugar, and a nitrogenous base attached to the 1' carbon. The sugar differs between the two nucleic acids: DNA contains deoxyribose, while RNA contains ribose. The two sugars are almost identical, but deoxyribose lacks an oxygen at the 2' carbon (it has an -H there rather than an -OH), which is the origin of the 'deoxy' in its name and part of why DNA is the more chemically stable, longer-term store.
Nucleotides join into a long chain called a polynucleotide. The phosphate on the 5' carbon of one nucleotide links to the 3' carbon (through its hydroxyl) of the next, so the sugars and phosphates form a continuous alternating backbone. Because one end of the finished strand exposes a free 5' phosphate and the other a free 3' hydroxyl, the strand has a definite direction, described as running 5' to 3'.
Pentose sugar: the five-carbon core of the nucleotide, deoxyribose in DNA or ribose in RNA.
Phosphate group: attached to the 5' carbon of the sugar; it is negatively charged, giving DNA its overall negative charge.
Nitrogenous base: attached to the 1' carbon; the four bases in DNA are adenine (A), guanine (G), cytosine (C) and thymine (T), while RNA uses uracil (U) in place of thymine.
Purines (double-ring): adenine and guanine. Pyrimidines (single-ring): cytosine, thymine and uracil.
Comparing DNA and RNA
DNA and RNA are both polynucleotides, but three structural differences set them apart, and each difference fits their different jobs. DNA is the stable, long-term archive of genetic information; RNA is a shorter-lived working copy involved in reading out that information and making proteins. Being able to state these three contrasts precisely is a very common exam requirement.
Sugar: DNA contains deoxyribose; RNA contains ribose.
Bases: DNA uses A, G, C and thymine; RNA uses A, G, C and uracil (uracil replaces thymine).
Strands: DNA is normally double-stranded (a double helix); RNA is normally single-stranded and much shorter.
Stability and role: the double strand and deoxyribose make DNA more stable for long-term storage; single-stranded ribose RNA is a versatile, short-term molecule.
The DNA double helix
In DNA, two polynucleotide strands wind around each other to form the famous double helix. The two sugar-phosphate backbones lie on the outside of the helix, like the side rails of a spiral ladder, while the nitrogenous bases point inwards and meet in the middle. The two strands are antiparallel: they run in opposite directions, so where one strand runs 5' to 3', its partner runs 3' to 5'. This opposite orientation is not a detail to memorise for its own sake, it is what allows the bases to line up and pair correctly all the way along the molecule.
Two strands: DNA is made of two polynucleotide strands twisted into a double helix.
Antiparallel: the strands run in opposite directions (one 5' to 3', the other 3' to 5').
Backbones outside: the sugar-phosphate backbones form the outer rails; the bases face inwards.
Base pairs inside: the paired bases form the 'rungs', holding the two strands a fixed distance apart.
Complementary base pairing and hydrogen bonds
The two strands are held together by pairing between their bases, and the pairing is not random. Adenine always pairs with thymine, and guanine always pairs with cytosine, a rule known as complementary base pairing. Each pair joins a double-ring purine to a single-ring pyrimidine, so every rung of the ladder is the same width and the helix stays uniform. The pairs are held by hydrogen bonds: two hydrogen bonds between A and T, and three between G and C. Individually these bonds are weak, but along a long molecule there are so many of them that the double helix is stable, while still able to be 'unzipped' locally when the information needs to be read or copied.
Notice the division of labour between the two kinds of bond. Strong covalent bonds run ALONG each backbone, holding a single strand together; weaker hydrogen bonds run BETWEEN the two strands, holding the pair together. That combination, strong within a strand and weak between strands, is exactly what a molecule needs if it must survive intact yet be opened easily for reading and copying.
How the base sequence stores information
The backbone is identical in every organism, so it carries no message. The information lives in the SEQUENCE of the bases, the order in which A, G, C and T appear along a strand. With four possible bases at every position, even a short stretch of DNA can be arranged in an enormous number of ways, and it is this order that encodes the instructions for making proteins. Because the sequence has a direction, it is always read and written 5' to 3'; the same four letters in the reverse order would spell a different message, just as the letters of a word only make sense read one way.
Chargaff's data and replication (HL)
Before the double helix was worked out, Erwin Chargaff measured the base composition of DNA from many different species. He found a consistent pattern: in every sample the amount of adenine equalled the amount of thymine, and the amount of guanine equalled the amount of cytosine, so %A = %T and %G = %C, even though the overall proportion of A-T to G-C varied from species to species. At the time this 1:1 matching was unexplained, but it becomes obvious once you know that A always pairs with T and G always pairs with C: every A on one strand is matched by a T on the other, and every G by a C. Chargaff's rules were therefore direct chemical evidence for complementary base pairing, and they let you calculate any base percentage once one is known.
The same feature that explains Chargaff's data also makes the molecule ideally suited to replication. Because each base has only one possible partner, each strand carries all the information needed to rebuild the other: it acts as a template. The weak hydrogen bonds between the base pairs allow the helix to be unzipped without breaking the strong backbone, exposing the bases so that free nucleotides can pair against each exposed strand. Since the strands are antiparallel, each is copied faithfully in the 5' to 3' direction, and the result is two identical double helices, each keeping one original strand. This is why Watson and Crick famously noted that the pairing 'immediately suggests a possible copying mechanism' for the genetic material.
Chargaff's rules: in double-stranded DNA, %A = %T and %G = %C.
Why: complementary base pairing means each A is matched by a T and each G by a C across the two strands.
Use it: if %G is known then %C is the same, and A and T share the remainder equally.
Significance: the fixed pairing means each strand exactly specifies its partner.
Common mistakes examiners penalise
Getting the pairing rules wrong — it is A with T and G with C. Writing A-G or A-C, or 'A pairs with U in DNA', loses marks; uracil belongs to RNA, not DNA.
Confusing bonds inside and between strands — covalent (sugar-phosphate) bonds run ALONG each backbone; hydrogen bonds run BETWEEN the strands at the base pairs. Do not say the strands are held together by covalent bonds.
Misstating the DNA/RNA differences — DNA has deoxyribose, thymine and two strands; RNA has ribose, uracil and one strand. Mixing any of these up is a common lost mark.
Explaining 'antiparallel' loosely — it means the two strands run in OPPOSITE directions (one 5' to 3', the other 3' to 5'), not that they are simply 'next to each other' or 'identical'.
Forgetting direction when writing a complementary strand — a correct set of bases with no 5'/3' labels usually forfeits the direction mark; always state that the new strand is antiparallel and give it 5' to 3'.
Naming a base as though it were a whole nucleotide — a nucleotide is a base PLUS a sugar PLUS a phosphate; 'adenine' alone is only the base.
Applying Chargaff's rule to single-stranded nucleic acids — %A = %T and %G = %C hold only for double-stranded DNA, not for a single strand or for RNA.
Where this leads
The structure you have built here is the foundation for much of the rest of biology. Complementary base pairing reappears in DNA replication (A1.2 HL and beyond), in transcription where a base sequence is copied into RNA, and in translation where that sequence is read three bases at a time to build a protein. The same logic, that a fixed base pair means one strand can specify another, underpins the whole flow of genetic information. Get the double helix, antiparallel strands and base pairing secure now, and every later topic on gene expression rests on solid ground.
Worked examples
See the formulas applied — reveal one step at a time, like the exam.
Describe the structure of a DNA molecule. [4]
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Model answer. A DNA molecule is made of two polynucleotide strands wound into a double helix. Each strand is a chain of nucleotides, and each nucleotide is composed of a deoxyribose sugar, a phosphate group and a nitrogenous base. The sugars and phosphates form a sugar-phosphate backbone on the outside of the helix, while the bases point inwards. The two strands run in opposite (antiparallel) directions. The bases pair together by complementary base pairing, adenine with thymine and guanine with cytosine, and each pair is held by hydrogen bonds (two for A-T, three for G-C).
One strand of a DNA molecule has the base sequence 5'-A T G C C A G T-3'. Write the base sequence of the complementary strand, and state the direction in which you have written it. [3]
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Step 1 — apply the pairing rules to each base. Going along the given strand, replace each base with its complement: A pairs with T, T with A, G with C, C with G. [1: correct complements chosen using A-T and G-C]
(HL) A sample of double-stranded DNA is found to contain 22% guanine. Calculate the percentage of thymine. [3]
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Step 1 — apply Chargaff's rule for G and C. In double-stranded DNA, %G = %C, so if guanine is 22% then cytosine is also 22%. [1]
How it all connects
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Glossary
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Quick check
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Revision flashcards
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The three components of a nucleotide
A pentose (five-carbon) sugar, a phosphate group, and a nitrogenous base. In DNA the sugar is deoxyribose; in RNA it is ribose.
Key takeaways
Review these before you close the topic — retrieval beats re-reading.
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Pentose sugar: the five-carbon core of the nucleotide, deoxyribose in DNA or ribose in RNA.
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Phosphate group: attached to the 5' carbon of the sugar; it is negatively charged, giving DNA its overall negative charge.
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Nitrogenous base: attached to the 1' carbon; the four bases in DNA are adenine (A), guanine (G), cytosine (C) and thymine (T), while RNA uses uracil (U) in place of thymine.
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Purines (double-ring): adenine and guanine. Pyrimidines (single-ring): cytosine, thymine and uracil.
Practice — then mark it
The whole point: a real Cambridge question, marked mark-by-mark.
Get a Paper 2 question marked: describe the structure of DNA and predict a complementary strand with full working
Get a Paper 2 question marked: describe the structure of DNA and predict a complementary strand with full working
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