17.4 – Protein Synthesis and Gene Expression

13. 17.4 – Protein Synthesis and Gene Expression • gene expression – the transfer of genetic information from DNA to protein • As described earlier, DNA is the genetic material in living things which gives the blueprint of how an organism develops. This blueprint, however, has to be put into a useful or structural form. In most living things, the main structural molecule is protein. Hence, DNA provides the blueprint for all the different proteins found in living organisms • Examples of protein structures: • 1) skeletal muscle tissue 4) enzymes • 2) smooth muscle tissue 5) transporters in cell membranes • 3) hormones • However, DNA is not directly used to make protein. Instead, DNA is copied to RNA, and RNA is used to make protein. This leads us to the central dogma of gene expression, proposed by Francis Crick. • DNA → RNA → protein • The use of DNA to produce RNA is called transcription. • The use of RNA to make protein is called translation.

14. The Genetic Code • Recall that in humans there are 20 amino acids (the basic units of proteins). However, there are only 4 different nucleotides. Therefore, if it only took 1 nucleotide to code for 1 amino acid only 4 amino acids could be produced. If 2 nucleotides in a row coded for 1 amino acid, you still could not code for all 20 amino acids (only 16 possible combinations). It takes combinations of 3 nucleotide sequences to code for 1 amino acid • Codon – the basic unit, or “word”, of the genetic code. It is a set of 3 adjacent nucleotides in DNA or mRNA that codes for amino acid placement on polypeptides. • (see table 17.2, p. 590) • Characteristics of the genetic code • → more than one codon can code for an amino acid • ex. UCA, UCU, UCG, and UCC all code for serine • → it is continuous (no spaces or overlap) • → universal code – is almost the same in all living things

15. Transcription (see fig 17.28, p. 591) • The main job of transcription is to make a RNA copy of a small section of the organism’s DNA (the particular gene needed to make a specific protein) • Messenger RNA (mRNA) – strand of RNA that carries genetic information from DNA to the protein synthesis machinery of the cell during transcription • RNA polymerase – main enzyme that catalyses the formation of mRNA from a DNA template • Sense strand – strand of nucleotides containing the instructions that direct protein synthesis. It is located within a stretch of DNA that includes a gene (not transcribed) • Antisense strand – strand of nucleotides that is complimentary to the sense strand (transcribed)

16. Steps in Transcription • 1) Initiation • → RNA polymerase binds to a particular sequence of nucleotides in the sense strand • → RNA polymerase opens up the double helix and begins inserting complimentary RNA nucleotides • 2) Elongation • → proceeds in the 5’ to 3’ direction (no Okazaki fragments) • → as the polymerase molecule proceeds, the DNA helix reforms and the mRNA molecule separates from the template DNA strand • 3) Termination and processing • → the RNA polymerase proceeds until it reaches a signal to stop and the RNA polymerase and mRNA completely separate from the DNA molecule • → a special sequence of nucleotides is added to the 5’ and 3’ ends • → introns are spliced out (removed), leaving only the exons • → the mRNA is transported out of the nucleus

17. Translation (see fig 17.29, p. 593) • Translation occurs outside the nucleus in eukaryotic cells, and involves several elements in order to occur. • Transfer RNA (tRNA) – RNA molecules that serve to link each codon along a mRNA strand with its complimentary amino acid • Transfer RNA has an unusual structure. They have a cloverleaf shape (single-stranded), and they contain an anticodon. • Anticodon – specialized base triplet located at one lobe of a tRNA molecule that recognizes its complimentary codon on an mRNA codon • At the 3’ end of a tRNA is an amino acid transport site. • Ribosomes – tiny two part structures found in the cell’s cytoplasm and attaches to the rough endoplasmic reticulum that helps to put together proteins. They bring together the mRNA strand, tRNA molecules carrying amino acids, and the enzymes involved in building proteins. • Ribosomal RNA (rRNA) – most common class of RNA molecules. During protein synthesis, these RNA molecules supply the site on the ribosome where the polypeptide is assembled.

18. The Translation Cycle • 1. mRNA binds to an active ribosome in such a way to expose two adjacent codons. • 2. The first tRNA molecule (carrying the amino acid methionine) binds to the codon AUG (start codon). • 3. A second tRNA molecule carrying an amino acid arrives at the codon adjacent to the first tRNA. • 4. Enzymes catalyze the formation of a peptide bond that joins the amino acid carried by the first tRNA to that carried by the second tRNA. At the same time, the polypeptide chain is transferred from the first tRNA to the second. • 5. The ribosome moves a distance of one codon along the mRNA strand. The first tRNA molecule detaches from the mRNA and goes to pick up another amino acid. The second tRNA now holds a growing polypeptide chain. A third tRNA molecule arrives at the exposed codon next to the second tRNA and the cycle repeats. • 6. When a “stop” codon is reached (UAG, UGA, UAA), the completed protein is released and the ribosome assembly comes apart.

19. Regulating Gene Expression • The rates of transcription and translation can be controlled to adjust to environmental conditions. For example, artic foxes have white fur in winter, but brown in warmer temperatures. • Factors that affect transcription and translation in living cells: • 1) changes in temp. or light • 2) the presence or absence of nutrients in the environment • 3) the presence of hormones in the body