DNA RNA and Protein Synthesis DNA and RNA

DNA, RNA, and Protein Synthesis

DNA and RNA In 1953, James Watson and Francis Crick developed the double-helix model of DNA. n DNA is a long molecule made up of subunits called nucleotides. (If you remember, nucleotides are the monomers of nucleic acids. ) n DNA nucleotides are made of three basic components: a 5 -carbon sugar called deoxyribose, a phosphate group and a nitrogenous base. – The deoxyribose and phosphates make up the “backbone” of DNA while the nitrogenous bases make up the “rungs” of the DNA ladder. n Both DNA & RNA are negatively charged due to phosphates n

Watson and Crick - 1953 Watson (left) and Crick displaying their model of DNA

Structure of DNA and RNA

Structure of DNA & Chromosomes

The Bases of DNA n There are four nitrogenous bases: adenine, thymine, guanine, and cytosine. – Adenine and thymine always pair up; guanine and cytosine always pair up. – Chargaff’s Rules: [A] = [T] and [G] = [C] DNA vs RNA (4: 43) Bases held together by hydrogen bonds

Nucleotide Sequences Exons: DNA nucleotide sequences that code for proteins n Introns: nucleotide sequences that do NOT code for proteins; removed from RNA before it leaves the nucleus n Codons: sequences of three bases that form the “words” to make amino acids; m. RNA carries them n – UCGCACGGU is read as UCG-CAC-GGU

Replication n DNA is copied through a process called replication. During replication, the DNA molecule separates into two strands, then produces two new strands. – Three principal enzymes involved: • DNA helicase – unzips the double helix • DNA polymerase – “proofreads” each new DNA strand to make sure it’s identical to the original • DNA ligase – stitches DNA back together

DNA Replication Bases held together by hydrogen bonds

Hello, RNA! n RNA is similar to DNA, but it has three main differences: – the sugar in RNA is ribose – RNA is single-stranded – RNA contains uracil in place of thymine n RNA has one main job – protein synthesis!

Three Types of RNA n There are three main types of RNA, all of which are involved in protein synthesis: – messenger RNA (m. RNA) • Carries protein-assembly instructions to ribosome – ribosomal RNA (r. RNA) • Helps regulate translation at the ribosome; comprises 60% of ribosome (40% protein) – transfer RNA (t. RNA) • Transfers individual amino acids to ribosomes so proteins can be assembled • Contains complementary anticodons for m. RNA’s codons

Transcription n In the nucleus, new RNA molecules are produced from nucleotide sequences of DNA in a process called transcription. – RNA polymerase is the principal enzyme involved in this process. • Its job is to construct RNA chains using DNA genes as templates n The strand of RNA contains the info needed to assemble proteins; it’s like an instruction manual.

Transcription

Translation n The readers of the instruction manuals are the ribosomes. n The ribosomes read the instructions (m. RNA molecules) and then make the necessary proteins through a process called translation. n t. RNA transfers amino acids to ribosome n t. RNA contains the complementary anticodons for the m. RNA codons

Translation anticodons

Mutations An agent, such as radiation or a chemical substance, that causes genetic mutation is a mutagen. n Mutations are changes in the genetic material n – They can be beneficial, deleterious, or have no effect (neutral) – Nearly all are neutral n There are two main types of mutations: – Gene mutations – Chromosomal mutations

Gene Mutations n Point mutations: involve changes in one or a few nucleotides; there are three main types: – Substitutions: one base is substituted with another (usually not a problem) • Also called a missense mutation – Insertions: an additional base is inserted into the nucleotide sequence (problem) – Deletions: a base is removed from the nucleotide sequence (problem)

Gene Mutations Insertions and deletions are called frameshift mutations because they shift the letters of the genetic message. Change the code different amino acid sequence useless proteins major problems!

Gene Mutations n Two other mutations: – 1. Nonsense: mutation that results in the coding for a stop codon rather than an amino acid • The shortened protein is generally nonfunctional or its function is impeded. • … GGT TGT CGA GCT … Gly Cys Arg • … GGT TGA Gly Cys Stop Ala

Gene Mutations n Two other mutations: – 2. Silent: change in the genetic sequence that does not change the protein sequence • This can occur because of redundancy in the genetic code where an amino acid may be encoded for by multiple codons. • … TTC TGT AGT GGT … Phe Cys Ser Gly • … TTC TGC AGT GGT … Phe Cys Ser Gly

Chromosomal Mutations Chromosomal mutations involve changes in the structure or number (e. g. trisomy) of chromosomes. n There are four main types: n – Deletion: loss of all or part of a chromosome – Duplication: extra copies produced – Inversion: reverses the direction of parts of chromosomes – Translocation: part of one chromosome breaks off and attaches to another

Chromosomal Mutations 101 (7: 20)

DNA and RNA Summary n In summary, DNA and RNA contain information for making not much else except proteins. – DNA is the “master plan” while RNA is the “blueprint”. – The “job sites” are the ribosomes. – The finished products are PROTEINS!!! n Protein Synthesis I (3: 30) n Protein Synthesis II (4: 27)

The Codon Wheel AUG GAC GGG CGC UAA

Using the Codon Wheel n So, how can we use the wheel? n Use this 3 -step process: – You’re given the DNA sequence TACCTGCCCGCGATT – Step 1: Separate the sequence into triplets • TAC CTG CCC GCG ATT – Step 2: Make the m. RNA sequence • AUG GAC GGG CGC UAA – Step 3: Use the codon wheel to translate the m. RNA codons into amino acids

From DNA to Protein