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Transcript
3.5 Transcription and translation – summary of mark schemes
3.5.1
Compare the structure of RNA and DNA.
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3.5.2
deoxyribose versus ribose;
thymine versus uracil;
two strands versus one / double helix versus single strand;
Outline DNA transcription in terms of the formation of an RNA strand complementary to the DNA strand by RNA polymerase.
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3.5.3
RNA polymerase controls transcription / is the enzyme used in transcription;
DNA is unwound by RNA polymerase;
DNA is split into two strands;
mRNA is made by transcription;
promoter region (by start of gene) causes RNA polymerase to bind;
anti-sense / template strand of DNA is transcribed;
direction of transcription is 5’  3’;
free nucleotide triphosphates used;
complementary base pairing between template strand and RNA nucleotides / bases;
RNA contains uracil instead of thymine;
terminator (sequence) stops RNA polymerase / transcription;
mRNA is released / RNA polymerase released;
Describe the genetic code in terms of codons composed of triplets of bases.
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3.5.4
composed of mRNA base triplets;
called codons;
64 different codons;
each codes for the addition of an amino acid to a growing polypeptide chain;
the genetic code is degenerate;
meaning more than one codon can code for a particular amino acid;
the genetic code is universal;
meaning it is the same in almost all organisms;
(AUG is the) start codon;
some (nonsense) codons code for the end of translation;
Explain the process of translation, leading to polypeptide formation.
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consists of initiation, elongation and termination;
mRNA is used as a template / guide;
mRNA translated in a 5' to 3' direction;
binding of ribosome to mRNA;
small sub-unit then large;
first / initiator tRNA binds to start codon / to small subunit of ribosome;
AUG is the start codon;
second tRNA binds to ribosome;
large subunit moves down mRNA after a second tRNA binds;
mRNA “read” in base triplets / codon;
each codon specifying addition of a particular amino acid to the growing polypeptide;
tRNA bring amino acids (to mRNA-ribosome complex);
amino acid / polypeptide on first tRNA is transferred / bonded to amino acid on second tRNA;
peptide bonds between amino acids / peptidyl transferase;
requires GTP;
movement of ribosome / small subunit of ribosome down the mRNA;
loss of tRNA and new tRNA binds;
reach a stop codon / termination;
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stop codon has no corresponding tRNA / amino acid / causes release of polypeptide;
polypeptide released;
tRNA activating enzymes link correct amino acid to each tRNA;
(activated) tRNA has an anticodon and the corresponding amino acid attached;
many ribosome / polyribosomes bind to same mRNA;