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Learn about the process of transcription and translation in protein synthesis, how genes direct the production of proteins, and the importance of DNA and RNA in this process.
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Transcription & Translation Protein Synthesis Biology 12
Genes direct the production of proteins that determine the phenotypical characteristics of organisms. Genes also direct the production of other physiologically essential proteins such as antibodies and hormones. Proteins drive cellular processes such as metabolism; determining physical characteristics and producing genetic disorders by their absence or presence in an altered form. Metabolism is a term that is used to describe all chemical reactions involved in maintaining the living state of the cells and the organism. Metabolism can be conveniently divided into two categories: Catabolism - the breakdown of molecules to obtain energy Anabolism – the synthesis of all compounds needed by cells )
The Central Dogma An organism’s genome is housed within the nucleus. Proteins are synthesized outside the nucleus, in the cytoplasm, on ribosomes. Since information for protein synthesis is specified by DNA (called the one gene-one polypeptide hypothesis), and DNA is not able to exist outside the nucleus, a problem exists as to how the blueprint of life is brought to the ribosomes.
The Connection Between Genes and Proteins Nucleic acids carry information in their nucleotide sequence. Proteins carry information in their amino acid sequence. To get from DNA (in nucleic acid language) to protein (in amino acid language) requires two steps. 1. Transcription- a DNA strand provides a template for the synthesis of a complementary RNA strand. This molecule is called mRNA (messenger RNA). DNA is too valuable to be allowed to exit the nucleus. This could lead to the death of the cell and possible the Death of the organism.
- use of mRNA provides protection for the Genetic information contained in DNA. - more protein can be made simultaneously because many mRNA copies of a gene can be made than if one strand of DNA left the nucleus. - each mRNA can be translated many times.
mRNA delivers the encoded genetic material to the ribosomes. The ribosomes translate the message into polypeptide chains, which are processed into proteins. This entire sequence is described as the Central Dogma of Molecular Genetics, first stated by Francis Crick in 1958.
Central Dogma In nucleus Produced in nucleus Travels to cytoplasm Produced in cytoplasm
Transcription vs Translation Transcription involves the copying of the information in DNA into mRNA. (copy from one medium to another- think of a medical or legal stenographer) Translation involves ribosomes using the Messenger RNA as a blueprint to synthesize a protein composed of amino acids. (converting into a different language, think English to French)
Definition: Transcription Transcription Nucleus Location Template (What is read) DNA To change DNA into a form that can make a protein Purpose Messenger RNA (mRNA) Outcome (End result)
Definition: Translation Translation Cytoplasm (by ribosome) Location Template (What is read) mRNA Amino acids assembled in particular order to make a protein Purpose Outcome (End result) Protein (polypeptide)
RNA RNA: How is it difference from DNA? - contains a ribose sugar - contains the base Uracil (not thymine) - single stranded - found in both nuclues and cytoplasm Purine Bases (double ring) Adenine & Guanine Pyrimidine Bases (single ring) Cytosine & Uracil Base Pairs: (purine always pairs with pyrimidine) Adenine + Uracil Guanine + Cytosine Image: www.biologycorner.com/bio1/DNA.html
Types of RNA Genetic information copied from DNA is transferred to 3 types of RNA: Messenger RNA: mRNA Copy of information in DNA that is brought to the ribosome and translated into protein by tRNA & rRNA Varies in length , the longer the gene the longer the mRNA> Transfer RNA: tRNA Brings the amino acid to the ribosome that mRNA coded for. Ribosomal RNA: rRNA Most of the RNA in cells is associated with structures known as ribosomes, the protein factories of the cells. Provides the construction site for the assembly of polypeptides. It is the site of translation where genetic information brought by mRNA is translated into actual proteins. Transcription & Translation
Transcription occurs in 3 steps: Initiation, Elongation and Termination Initiation: RNA polymerase binds to the DNA at a specific site known as a promotor. DNA: A T G C A A RNA: U A C G U U The RNA transcript is known as elongation. After the RNA polymerase passes the end of the gene, it stops transcribing which is termination.
Transcription : ‘to copy’ Initiation: RNA polymerase binds to DNA at ‘promoter’ untwists the double helix 10 to 20 bases at a time Elongation: RNA polymerase builds mRNA From DNA 3’ end Uses complimentary base pairing Remember: thymine (T) is replaced by uracil (U)
Termination: RNA polymerase reaches end of gene. Stops transcribing Double helix reforms as mRNA molecule peels away. End Result: mRNA breaks away from DNA mRNA exits nucleus If there is a high demand for a protein, the cell can have several RNA polymerases transcribing the gene at the same time to produce several mRNA’s.
Translation: ‘new language’ Initiation: Ribosome binds at a specific sequence on the mRNA. The ribosome moves along the mRNA three nucleotides at a time. This is called a codon. Each set of three (a codon) codes for an amino acid. Why? There are only 4 bases but 20 amino acids. 41= 4 (1 base=1 acid) 42= 16 43= 64
The codon AUG not only codes for the amino acid Methionine, but it also indicates the start of a translation. Some amino acids are coded for by two or more codons but a given codon ALWAYS only codes for one amino acid. GAA and GAG both code for glutamic acid, but never mean any other amino acid.
Elongation: Ribosome moves along mRNA From mRNA 5’ end 3 nucleotides of mRNA = codon = amino acid The “interpreter” tRNA delivers the proper complimentary base to the ribosome. Anticodons are blocks of 3 tDNA bases that actually attach to the correct protein. The anticodon( tRNA) binds by complimentary base pairing to the nucleotides of the codon. Example: if the codon on a mRNA is UUU, a tRNA with an AAA anticodon will bind to it. The ribosome links adjacent amino acids with a peptide bond, causing the amino acid to let go of it tRNA. The finished protein has a sequence of amino acids that have been determined by the mRNA base sequence which has been translated by the tRNA.
The ribosome then adds each amino acid and the polypeptide chain is elongated. Elongation occurs until a stop signal occurs. Termination: Ribosome reaches stop codon Stops translating End Result: Ribosome falls off mRNA Protein (polypeptide chain) is released
Start and Stop Codons Start Codon: Begins translation AUG (universal start codon) ALSO Codes for methionine (Met) Sometimes GUG or UUG Stop Codon: Ends translation UGA, UAA, UAG
The Whole Next amino acid to be added to polypeptide Picture Growing polypeptide tRNA mRNA
Example DNA template: 3’ TAC ACA CGG AAT GGG TAA AAA ACT 5’ Complimentary DNA Read from DNA template (start reading at 3’) mRNA codon Read from DNA template (start reading at 3’) tRNA anticodon Read from mRNA Amino Acids (protein) Read from mRNA
Task A: #2 – Central Dogma DNA makes RNA (mRNA) through transcription RNA makes proteins through translation
#4 – RNA types mRNA Messenger RNA End product of transcription Takes message from DNA into cytoplasm Used by ribosome to make protein tRNA Transfer RNA Delivers amino acid to ribosome rRNA Ribosomal RNA Helps form and maintain ribosomes
#5 – DNA vs. RNA DNA Sugar – deoxyribose Double stranded Base pair – thymine Stays in nucleus Can replicate itself Longer strands RNA Sugar – ribose Single Stranded Base pair – uracil Can leave nucleus Cannot replicate itself Shorter strands
#6 – Transcription/Translation Transcription Purpose: To make mRNA from DNA Location: Nucleus Translation Purpose: To make a specific protein from mRNA Location: Cytoplasm (ribosome)
#9 – Stop vs. Start Codon Start Codon mRNA code Tells ribosome to begin translation Example: AUG Also codes for methionine And: UUG, GUG Stop Codon mRNA code Stops translation of that specific amino acid chain Examples: UAA, UAG, UGA
#10 – Transcribe to mRNA DNA: GGA TCA GGT CCA GGC AAT TTA GCA TGC CCC AA *mRNA*: CCU AGU CCA GGU CCG UUA AAU CGU ACG GGG UU
#11 – Translate to Amino Acids mRNA sequence divided into codons: GGC AUG GGA CAU UAU UUU GCC CGU UGU GGU GGG GCG UGA *Protein translation*: Gly Met(start) Gly His Tyr Phe Ala Arg Cys Gly Gly Ala (stop)
Task B: #2 – Transcribe to mRNA DNA: TAC TAC GGT AGG TAT A *mRNA*: AUG AUG CCA UCC AUA U
Task C: #3 – Anticodons
#4 – Change in 3rdBase May Not Result in Error Why not? Amino acids have more than one codon Example: proline Codons CCU, CCC, CCA, and CCG CC - always codes for proline Third base/nucleotide does not matter
#6 – Translate to Amino Acids mRNA: GGC CCA UAG AUG CCA CCG GGA AAA GAC UGA GCC CCG *Protein translation*: Met (start) Pro Pro Gly Lys Asp (stop)