RNA and Protein Synthesis

1. RNA and Protein Synthesis

2. The Function of DNA • The DNA molecule contains all of your hereditary information in the form of genes. • Genes are portions of the DNA molecule that code for the production of specific types of proteins. • However, DNA is confined to the nucleus, while proteins are made by ribosomes in the cytoplasm. • Thus, a messenger molecule is needed. http://www.accessexcellence.org/RC/VL/GG/images/genes.gif

3. Comparing DNA and RNA • RNA is the nucleic acid that acts as a messenger between DNA and the ribosomes. • The RNA produced during transcription is structurally different from DNA in 3 basic ways: • 1. The sugar in RNA is ribose whereas the sugar in DNA is deoxyribose. • 2. RNA is single stranded while DNA is double stranded. • 3. RNA contains a base called uracil instead of thymine. http://www.dkimages.com/discover/previews/769/85011519.JPG

4. The Role of RNA • RNA molecules have many functions, but in the majority of cells, most RNA molecules are involved in protein synthesis. • Protein synthesis is the assembly of amino acids into proteins.

5. Types of RNA • The RNA produced during transcription is modified into 3 basic types: • 1. messenger RNA (mRNA) copies one segment (or gene)on one strand of DNA in the nucleus and carries that information to the ribosome. • 2. ribosomal RNA (rRNA) makes up a large part of the ribosome and is responsible for reading and decoding mRNA. • 3. transfer RNA (tRNA) carries amino acids to the ribosome where they are joined to form proteins. http://images.encarta.msn.com/xrefmedia/zencmed/targets/illus/ilt/T068340A.gif

6. Protein Synthesis • During protein synthesis, genes copied onto RNA are expressed by the production of specific types of proteins. • Protein synthesis involves two processes: • 1. Transcription – process in which a RNA copy of a segment (gene) of DNA is made. • 2. Translation – the decoding of mRNA message into a polypeptide chain (protein).

7. Transcription Transcription occurs on the DNA in the nucleus. • RNA Polymerase binds to DNA at a promoter and separates the DNA strands. • RNA Polymerase uses one strand of DNA as a template to assemble complementary nucleotides into a strand of RNA. • Transcribed mRNA leaves the nucleus and goes to the ribosome.

8. Transcription Practice DNA: AACTGGTACGTA mRNA: UUGACCAUGCAU DNA: ATGTTCACTGGA mRNA: UACAAGUGACCU DNA: GTTCATGCATAT mRNA: CAAGUACGUAUA DNA: TGCCATCGATTC mRNA: ACGGUAGCUAAG DNA: CTGATGCTGATA mRNA: GACUACGACUAU

9. Decoding mRNA • The sequence of bases in an mRNA molecule serves as instructions for the order in which amino acids are joined to produce a polypeptide. • Ribosomes decode these instructions by using codons, sets of 3 bases that each code for one amino acid. • Each codon is matched to an anticodon on the tRNA to determine the order of the amino acids. http://www.gwu.edu/~darwin/BiSc150/One/codon.gif

10. Translation-occurs in the cytoplasm at the ribosomes. • mRNA attaches to a ribosome • Translation begins at AUG, the start codon • tRNA brings an amino acid to the ribosome • The tRNA binds to the mRNA by matching its anticodon to the codon the mRNA • The ribosome moves along the mRNA as each tRNA drops of its amino acid

11. The ribosome joins amino acids with peptide bonds and the tRNAs leave the ribosome • The process continues until the ribosome reaches the STOP codon • The result is a polypeptide. (protein)

12. Using a Codon Chart • A codon chart can be used to determine the sequence of the amino acids in the polypeptide. • The mRNA bases or CODONS are used to find the amino acid. http://www.safarikscience.org/biologyhome/7_dna/codon_question.png

13. CODON CHART

14. Decoding Practice • For the following examples, give the appropriate mRNA sequence and amino acid sequence. (Remember: U replaces T in mRNA.) Example 1: DNA: TAC GCA TGG AAT mRNA: AUG CGU ACC UUA Amino Acids: Met Arg Thr Leu Example 2: DNA: CGT GGA GAT ATT mRNA: GCA CCU CUA UAA tRNA: CGU GGA GAU AUU Amino Acids: Ala Pro Leu stop