DNA (DNA = deoxyribonucleic acid) • DNA is the genetic material of all living cells and of many viruses. • DNA is: an alpha double helix of two polynu...
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DNA is the genetic material of all living cells and of many viruses. DNA is: an alpha double helix of two polynucleotide strands. The genetic code is the sequence of bases on one of the strands. A gene is a specific sequence of bases which has the information for a particular protein. DNA is self-replicating - it can make an identical copy of itself. Replication allows the genetic information to pass faithfully to the next generation. Replication occurs during the ‘S’ (= synthesis) stage of interphase just before nuclear division. The chromosomes contain 90% of the cell’s DNA. 10% is present in mitochondria and chloroplasts. Adenine (A) and Guanine (G) are purine bases Thymine (T) and Cytosine (C) are pyrimidine bases Hydrogen bonds link the complementary base pairs: Two between A and T (A = T) Three between G and C (G ≡ C) A single unit in the chain is a nucleotide. o This consists of a phosphate group, o a pentose sugar (D = DNA; R = RNA) and o an organic base (ATGC = DNA; AUGC = RNA) o o
RNA (RNA = ribonucleic acid) • •
•
Three different types of RNA, (messenger (mRNA), transfer (tRNA) ribosomal (rRNA)) All are made in the nucleus (transcription) o ribosomes are synthesised in the nucleolus; o mRNA prepared there too – introns removed All types of RNA are involved in protein synthesis: o mRNA: copies the information from the DNA. o tRNA: carries the specific amino acid to the mRNA in contact with the ribosome. o rRNA: makes up 55% of ribosomes (the other 45% = protein).
NB. Some RNA molecules can function as enzymes.
Differences between DNA and RNA • • • • • •
DNA is double stranded; RNA is a single stranded N.B. ATP is also a nucleotide, with ribose as the pentose sugar. DNA contains the pentose sugar deoxyribose; RNA contains the pentose sugar ribose. DNA has the base Thymine (T) but not Uracil (U); RNA has U but not T. DNA is very long (billions of bases); RNA is smaller (hundreds to thousands of bases) DNA is self-replicating, RNA is copied from the DNA so it is not self-replicating
The genetic information is held within the base sequence along a DNA strand. A codon is a sequence of three nucleotides, coding for one amino-acid. The genetic code is universal, thus all life must have had a common ancestor (i.e. evolution)
Coding structures (Exons) • •
These are the parts of the DNA that contain the code for the synthesis of protein or RNA. These coding sequences are present within genes.
Non-coding Structures. • • •
• •
This is DNA that does not contain information for the synthesis of protein or RNA. The non-coding sequences are found both between genes and within genes (= introns). These non-coding sequences have been termed ‘junk DNA’ but they: o do play a role in gene expression (i.e. whether a gene is switched ‘on’ or ‘off’) o act as spacer material, o permit the synthesis of many new proteins and o play an important role in evolution. Non-coding DNA makes up 95% of human DNA. Non-coding DNA segments within genes are called introns.
DNA Replication This takes place during the S stage of interphase • • • • • • •
Nucleotides are synthesised in huge quantities in the cytoplasm. An enzyme unzips the two complementary strands of DNA. New complementary nucleotides link to the exposed bases on the separated strands. The general name for this group of enzymes is DNA polymerase. A new complementary strand is built along each ‘old’ strand. Two DNAs, identical to the original and each other, are now present. Each new DNA molecule is thus ‘half old’ and ‘half new’ o ‘semi-conservative replication’.
Protein Synthesis
Gene - A section of DNA containing a particular sequence of bases that codes for a specific protein.
Protein Synthesis - The transcription of a specific DNA base sequence into mRNA and its translation, by a ribosome, into a particular amino acid sequence forming a protein.
Genetic Code • • • •
The universal code that determines the function of all possible triplets of DNA / mRNA. Most triplets specify a particular amino acid (= a codon). Some triplets function as a start or stop signal for protein synthesis. It is a degenerate code as a particular amino acid may be coded for by more than one codon.
Process of Protein Synthesis – transcription and translation Transcription – DNA base sequence to mRNA base sequence • • •
• • •
The ‘code’ for the protein is carried by one of the DNA strands in the gene. An enzyme separates the two DNA strands at the gene locus exposing the gene sequence. A complementary copy - mRNA - is made of the gene sequence – o new nucleotides form a complementary RNA strand o using the DNA gene sequence strand as a ‘master’ o the enzyme RNA polymerase links the new nucleotides forming mRNA. Uracil (U) is the complementary base to adenine in RNA, thymine (T) is not found in RNA. The complementary RNA copy is called messenger RNA (mRNA). The mRNA separates from the DNA strand and passes from the nucleus to the cytoplasm.
A ribosome binds to the start point of the mRNA. The ribosome will ‘decode’ the mRNA in sets of three bases (a codon). Each codon specifies a particular amino acid. The sequence of bases on the mRNA determines the sequence of amino acids in the protein – any change = a mutation Two codons of the mRNA are exposed in turn. Two complementary tRNA molecules attach to these two mRNA triplets. The amino acids of the tRNA bond together (peptide bond – condensation reaction) The leading tRNA detaches from its amino acid and from the mRNA. The ribosome ‘moves’ to the next codon and another complementary tRNA attaches. The newly arrived complementary tRNA then adds a new amino acid. The process repeats, codon by codon, to the end of the mRNA (until a stop codon is reached). The amino acid sequence is now complete. The polypeptide (amino acid chain) folds giving the protein its normal functional shape. Primary structure = amino-acid sequence (determined by DNA sequence) Secondary structure = many H- bonds making o Alpha helix (very common) or o Beta-pleated sheet (rare – butterfly wings and silk) o Thus affected by pH, temperature Tertiary structure = disulphide bridges and further H-bonds – forms active sites Quaternary structure (rare) – only haemoglobin (Van der Waal’s forces)
Ribosomal RNA (rRNA) A ribosome is roughly 50% protein and 50% RNA (known as rRNA). Transfer RNA (tRNA) • tRNA is found in large amounts in the cytoplasm. • Single stranded but folded back on itself with three exposed bases (‘anticodon’) at one end and a particular amino acid at the opposite end. • tRNAs are ‘adapters’ linking amino acids to nucleic acids in protein synthesis. • There are 64 (4 x 4 x 4) possible triplets; • there are 61 tRNAs - the other 3 are ‘stop’ signals • There are only 20 different amino-acids, so o each amino-acid is coded for by more than one codon (tRNA); o thus the code is degenerate (or ‘semi-redundant’) Note: transcription occurs in the nucleus; translation occurs in the cytoplasm.
