Presentation is loading. Please wait.

Presentation is loading. Please wait.

Biology 102 Gene Regulation and Expression Part 2.

Published byKenneth Berry Modified over 8 years ago

Similar presentations

Presentation on theme: "Biology 102 Gene Regulation and Expression Part 2."— Presentation transcript:

1 Biology 102 Gene Regulation and Expression Part 2

2 Lecture outline 1.Translation Review of what translation is Review of what translation is Types of RNA and their functions Types of RNA and their functions Overview of translation Overview of translation Details of translation Details of translation 2.Information flow through cell

3 Review: Information Flow DNA=>mRNA=>Protein

4 12 catalytic site tRNA docking sites Attached amino acid Transfer RNA Small subunit Ribosome contains rRNA mRNA Large subunit C A G A U G G A G U U A U G G mRNA A G U Met anticodon Three Types of RNA (review)

5 Translation: An Overview

6 Translation: Initiation A tRNA with an attached methionine amino acid binds to a small ribosomal subunit, forming an initiation complex. A tRNA with an attached methionine amino acid binds to a small ribosomal subunit, forming an initiation complex.

7 Translation: Initiation (2) The initiation complex binds to end of mRNA and travels down until it encounters an AUG codon in the mRNA. The initiation complex binds to end of mRNA and travels down until it encounters an AUG codon in the mRNA. The anticodon of the tRNA in the initiation complex forms base pairs with the AUG codon. The anticodon of the tRNA in the initiation complex forms base pairs with the AUG codon.

8 Translation: Initiation (3) The large ribosomal subunit binds to the small subunit, with the mRNA between the two subunits. The large ribosomal subunit binds to the small subunit, with the mRNA between the two subunits. The methionine tRNA is in the first tRNA site on the large subunit. The methionine tRNA is in the first tRNA site on the large subunit.

9 Translation: Elongation 1 The second tRNA enters the second tRNA site The second tRNA enters the second tRNA site The tRNA that binds must be able to match its anticodon (CAA in this example) to base pair with the codon (GUU in this example) in the mRNA. The tRNA that binds must be able to match its anticodon (CAA in this example) to base pair with the codon (GUU in this example) in the mRNA. tRNAs with a CAA anticodon carry an attached valine amino acid, which was added to it by enzymes in the cytoplasm. tRNAs with a CAA anticodon carry an attached valine amino acid, which was added to it by enzymes in the cytoplasm.

10 Translation: Elongation 2 The catalytic site on the large subunit catalyzes the formation of a peptide bond linking the amino acids The catalytic site on the large subunit catalyzes the formation of a peptide bond linking the amino acids The two amino acids are now attached to the tRNA in the second binding position. The two amino acids are now attached to the tRNA in the second binding position.

11 Translation: Elongation 3 The "empty" tRNA is released and the ribosome moves down the mRNA, one codon to the right. The "empty" tRNA is released and the ribosome moves down the mRNA, one codon to the right. The tRNA that is attached to the two amino acids is now in the first tRNA binding site and the second tRNA binding site is empty. The tRNA that is attached to the two amino acids is now in the first tRNA binding site and the second tRNA binding site is empty.

12 Translation: Elongation 4 Another tRNA enters the second tRNA binding site carrying its attached amino acid. Another tRNA enters the second tRNA binding site carrying its attached amino acid. The tRNA has an anticodon that pairs with the codon. (Here, the CAU mRNA codon pairs with a GUA tRNA anticodon.) The tRNA has an anticodon that pairs with the codon. (Here, the CAU mRNA codon pairs with a GUA tRNA anticodon.) The tRNA molecule carries the amino acid histidine (his). The tRNA molecule carries the amino acid histidine (his).

13 Translation: Elongation 5 The catalytic site forms a new peptide bond, in this example, between the valine and the histidine. The catalytic site forms a new peptide bond, in this example, between the valine and the histidine. A three-amino acid chain is now attached to the tRNA in the second tRNA binding site. A three-amino acid chain is now attached to the tRNA in the second tRNA binding site. The empty tRNA in the first site is released and the ribosome moves one codon to the right. The empty tRNA in the first site is released and the ribosome moves one codon to the right.

14 Translation: Termination Binding of tRNAs, & formation of peptide bonds continues. Binding of tRNAs, & formation of peptide bonds continues. Ribosome reaches STOP codon (UAG). Ribosome reaches STOP codon (UAG). Protein "release factors" signal the ribosome to release the protein. Protein "release factors" signal the ribosome to release the protein. The mRNA is also released and large & small subunits separate. The mRNA is also released and large & small subunits separate.

15 G G G A G C G A U U U C A A C A U C C U MethionineGlycineValineetc. G G G A G T T C T G A template DNA strand (a) complementary DNA strand (b) mRNA (c) tRNA (d) protein amino acids anticodons codons gene etc. etc. etc. G T C C C C A A A T C Review: From DNA to amino acid chain

16 Amino Acids Active Protein Overview of Information Flow within the cell Inactive Protein (Cytoplasm) DNA (Nucleus) rRNAtRNA 1 Transcription + Proteins Ribosomes tRNA tRNA-AA mRNA mRNA 2 Translation 3 Modification Product Substrate 4 Degradation

17 The End

Download ppt "Biology 102 Gene Regulation and Expression Part 2."

Similar presentations

Transcription and Translation

Transcription and Translation
Molecular Genetics DNA RNA Protein Phenotype Genome Gene

Molecular Genetics DNA RNA Protein Phenotype Genome Gene
Cell Division, Genetics, Molecular Biology

Cell Division, Genetics, Molecular Biology
Cell Division, Genetics, Molecular Biology

Cell Division, Genetics, Molecular Biology
Review: The flow of genetic information in the cell is DNA  RNA  protein  The sequence of codons in DNA spells out the primary structure of a polypeptide.

Review: The flow of genetic information in the cell is DNA  RNA  protein  The sequence of codons in DNA spells out the primary structure of a polypeptide.
From DNA to Protein.

From DNA to Protein.
6.3 Translation: Synthesizing Proteins from mRNA

6.3 Translation: Synthesizing Proteins from mRNA
 Assemble the DNA  Follow base pair rules  Blue—Guanine  Red—Cytosine  Purple—Thymine  Green--Adenine.

 Assemble the DNA  Follow base pair rules  Blue—Guanine  Red—Cytosine  Purple—Thymine  Green--Adenine.
From gene to protein. DNA:nucleotides are the monomers Proteins: amino acids are the monomers DNA:in the nucleus Proteins:synthesized in cytoplasm.

From gene to protein. DNA:nucleotides are the monomers Proteins: amino acids are the monomers DNA:in the nucleus Proteins:synthesized in cytoplasm.
PROTEIN SYNTHESIS.

PROTEIN SYNTHESIS.
8.4 DNA Transcription 8.5 Translation

8.4 DNA Transcription 8.5 Translation
Protein Synthesis The genetic code – the sequence of nucleotides in DNA – is ultimately translated into the sequence of amino acids in proteins – gene.

Protein Synthesis The genetic code – the sequence of nucleotides in DNA – is ultimately translated into the sequence of amino acids in proteins – gene.
Activate Prior Knowledge

Activate Prior Knowledge
RNA carries DNA’s instructions.

RNA carries DNA’s instructions.
Fig. 12-2, p.187. Fig. 12-5, p.190 Fig. 12-6, p.191 2-nanometer diameter overall 0.34-nanometer distance between each pair of bases 3.4-nanometer length.

Fig. 12-2, p.187. Fig. 12-5, p.190 Fig. 12-6, p nanometer diameter overall 0.34-nanometer distance between each pair of bases 3.4-nanometer length.
Protein Translation From Gene to Protein Honors Biology Ms. Kim.

Protein Translation From Gene to Protein Honors Biology Ms. Kim.
Transcription Transcription is the synthesis of mRNA from a section of DNA. Transcription of a gene starts from a region of DNA known as the promoter.

Transcription Transcription is the synthesis of mRNA from a section of DNA. Transcription of a gene starts from a region of DNA known as the promoter.
Hemophilia- Caused by a defect in a single gene cannot produce all the proteins necessary for blood clotting Depend on expensive injections of clotting.

Hemophilia- Caused by a defect in a single gene cannot produce all the proteins necessary for blood clotting Depend on expensive injections of clotting.
Protein Synthesis: Translation Making the Protein from the Code.

Protein Synthesis: Translation Making the Protein from the Code.
CFE Higher Biology DNA and the Genome Translation.

CFE Higher Biology DNA and the Genome Translation.

Similar presentations

Ads by Google