1. Genes and Protein Synthesis
Chapter 7
Genes and Protein Synthesis

2. One Gene-One Polypeptide Hypothesis
DNA contains all of our hereditary information
Genes are located in our DNA
~25,000 genes in our DNA (46 chromosomes)
Each Gene codes for a specific polypeptide

3. Main Idea
Central Dogma
Francis Crick (1956)

4. Overall Process Transcription Translation DNA to RNA
Gene 1
Gene 3
DNA molecule
Transcription
DNA to RNA
Translation
Assembly of amino acids into polypeptide
Using RNA
Gene 2
DNA strand
TRANSCRIPTION
RNA
Codon
TRANSLATION
Polypeptide
Amino acid

5. Key Terms RNA transcription TATA box Introns, Exons mRNA, tRNA, rRNA
Initiation, Elongation, Termination
TATA box
Introns, Exons
mRNA, tRNA, rRNA
Translation
Ribosome
Codon
Amino Acids
Polypeptide

6. Adenine pairs with Thymine Adenine pairs with Uracil
DNA
RNA
Double stranded
Single stranded
Adenine pairs with Thymine
Adenine pairs with Uracil
Guanine pairs with Cytosine
Deoxyribose sugar
Ribose sugar

7. DNA to Protein Protein is made of amino acid sequences 20 amino acids
How does DNA code for amino acid?

8. Genetic COde Codon AA are represented by more than one codon
Three letter code
5’ to 3’ order
Start codon
Stop codon
AA are represented by more than one codon
61 codons that specify AA

9. Amino acids
Abbreviated
Three letters

10. Transcription DNA to RNA Occurs in nucleus Three process Initiation
RNA polymerase
Transcription
DNA of gene
Promoter
DNA
Terminator
DNA
DNA to RNA
Occurs in nucleus
Three process
Initiation
Elongation
Termination
Initiation
Elongation
Termination
Growing RNA
Completed RNA
RNA polymerase

11. initiation RNA polymerase binds to DNA Binds at promoter region
TATA box
RNA polymerase unwinds DNA
Transcription unit
Part of gene that is transcribed

12. initiation Transcription factors bind to specific regions of promoter
Provide a substrate for RNA polymerase to bind beginning transcription
Forms transcription initiation complex

13. Elongation RNA molecule is built Primer not needed 5’ to 3’
RNA polymerase
Primer not needed
5’ to 3’
3’ to 5’ DNA is template strand
Coding strand
DNA strand that is not copied
Produces mRNA
Messenger RNA
DNA double helix reforms

14. Termination RNA polymerase recognizes a termination sequence – AAAAAAA
Nuclear proteins bind to string of UUUUUU on RNA
mRNA molecule releases from template strand

16. Post-transcriptional modifications
Pre-mRNA undergoes modifications before it leaves the nucleus
Poly(A) tail
Poly-A polymerase
Protects from RNA digesting enzymes in cytosol
5’ cap
7 G’s
Initial attachment site for mRNA’s to ribosomes
Removal of introns

17. Splicing the pre-MRNa DNA comprised of Spliceosome
Exons – sequence of DNA or RNA that codes for a gene
Introns – non-coding sequence of DNA or RNA
Spliceosome
Enzyme that removes introns from mRNA

18. Splicing Process
Spliceosome contains a handful of small ribonucleoproteins
snRNP’s (snurps)
snRNP’s bind to specific regions on introns

19. Alternative Splicing
Increases number and variety of proteins encoded by a single gene
~25,000 genes produce ~100,000 proteins

20. Translation mRNA to protein Ribosomes read codons
tRNA assists ribosome to assemble amino acids into polypeptide chain
Takes place in cytoplasm

21. tRNA Contains Are there 61 tRNA’s to read 61 codons? triplet anticodon
amino acid attachment site
Are there 61 tRNA’s to read 61 codons?

22. TRNa: Wobble Hypothesis
First two nucleotides of codon for a specific AA is always precise
Flexibility with third nucleotide
Aminoacylation – process of adding an AA to a tRNA
Forming aminoacyl-tRNA molecule
Catalyzed by 20 different aminoacyl-tRNA synthetase enzymes

23. Ribosomes Translate mRNA chains into amino acids
Made up of two different sized parts
Ribosomal subunits (rRNA)
Ribosomes bring together mRNA with aminoacyl-tRNAs
Three sites
A site - aminoacyl
P site – peptidyl
E site - exit

24. Translation process Three stages Initiation Elongation Termination
Amino acid
Translation process
Polypeptide
A site
P site
Anticodon
mRNA
Three stages
Initiation
Elongation
Termination 1
Codon recognition
mRNA movement
Stop codon
New peptide bond 2
Peptide bond formation 3
Translocation

25. Initiation Reading frame is established to correctly read codons
Ribosomal subunits associate with mRNA
Met-tRNA (methionine)
Forms complex with ribosomal subunits
Complex binds to 5’cap and scans for start codon (AUG) – known as scanning
Large ribosomal subunit binds to complete ribosome
Met-tRNA is in P-site
Reading frame is established to correctly read codons

26. Elongation Amino acids are added to grow a polypeptide chain
A, P, and E sites operate
4 Steps

27. Termination A site arrives at a stop codon on mRNA
UAA, UAG, UGA
Protein release factor binds to A site releasing polypeptide chain
Ribosomal subunits, tRNA release and detach from mRNA

28. polysome a b
What molecules are present in this photo?
Red object = ?

29. Prokaryotic RNA transcription/Translation
Throughout cell
Single type of RNA polymerase transcribes all types of genes
No introns
mRNA ready to be translated into protein
mRNA is translated by ribosomes in the cytosol as it is being transcribed

30. Review What is a gene? Where is it located?
What is the main function of a gene?
Do we need our genes “on” all the time?
How do we turn genes “on” or “off”?

31. Regulating Gene expression
Proteins are not required by all cells at all times
Regulated
Eukaryotes – 4 ways
Transcriptional (as mRNA is being synthesized)
Post-transcriptional (as mRNA is being processed)
Translational (as proteins are made)
Post-translational (after protein has been made)
Prokaryotes
lacOperon
trpOperon

32. Transcriptional regulation
Most common
DNA wrapped around histones keep gene promoters inactive
Activator molecule is used (2 ways)
Signals a protein remodelling complex which loosen the histones exposing promoter
Signals an enzyme that adds an acetyl group to histones exposing promoter region

33. Transcriptional regulation
Methylation
Methyl groups are added to the cytosine bases in the promoter of a gene (transcription initiation complex)
Inhibits transcription – silencing
Genes are placed “on hold” until they are needed
E.g. hemoglobin

34. Agouti mice

35. Post transcriptional regulation
Pre-mRNA processing
Alternative splicing
Rate of mRNA degradation
Masking proteins – translation does not occur
Embryonic development
Hormones - directly or indirectly affect rate
Casein – milk protein in mammary gland
When casein is needed, prolactin is produced extending lifespan of casein mRNA

36. Translational regulation
Occurs during protein synthesis by a ribosome
Changes in length of poly(A) tail
Enzymes add or delete adenines
Increases or decreases time required to translate mRNA into protein
Environmental cues

37. Post-translational regulation
Processing
Removes sections of protein to make it active
Cell regulates this process (hormones)
Chemical modification
Chemical groups are added or deleted
Puts the protein “on hold”
Degradation
Proteins tagged with ubiquitin are degraded
Amino acids are recycled for protein synthesis

38. Prokaryotic Regulation
lacOperon
Regulates the production of lactose metabolizing proteins

39. Prokaryotic Regulation
trpOperon
Regulates the expression of tryptophan enzymes

40. Cancer Lack regulatory mechanisms Mutations in genetic code (mutagens)
Probability increases over lifetime
Radiation, smoking, chemicals
Mutations are passed on to daughter cells
Can lead to a mass of undifferentiated cells (tumor)
Benign and malignant
Oncogenes
Mutated genes that once served to stimulate cell growth
Cause undifferentiated cell division

41. cancer

42. Genetic mutations Positive and negative Small-Scale – single base pair
Natural selection – evolution
Cancer –death
Small-Scale – single base pair
Point mutations
Substitution, insertion/deletion, inversion
Large-Scale – multiple base pairs

43. Small-scale mutations
Four groups
Missense, nonsense, silent, frameshift
Lactose, sickle cell anemia
SNPs – single nucleotide polymorphisms
Caused by point mutations

44. Missense mutation Change of a single base pair or group of base pairs
Results in the code for a different amino acid
Protein will have different sequence and structure and may be non-functional or function differently

45. Nonsense mutation Change in single base pair or group of base pairs
Results in premature stop codon
Protein will not be able to function

46. Silent mutation Change in one or more base pairs
Does not affect functioning of a gene
Mutated DNA sequence codes for same amino acid
Protein is not altered

47. Frameshift mutation
One or more nucleotides are inserted/deleted from a DNA sequence
Reading frame of codons shifts resulting in multiple missense and/or nonsense effects
Any deletion or insertion of base pairs in multiples of 3 does not cause frameshift

48. Large-scale mutations
Multiple nucleotides, entire genes, whole regions of chromosomes

49. Large-scale mutations
Amplification – gene duplication
Entire genes are copied to multiple regions of chromosomes

50. Large-scale mutations
Large-scale deletions
Entire coding regions of DNA are removed
Muscular Dystrophy

51. Large-scale mutations
Chromosomal translocation
Entire genes or groups of genes are moved from one chromosome to another
Enhance, disrupt expression of gene

52. Large-scale mutations
Inversion
Portion of a DNA molecule reverses its direction in the genome
No direct result but reversal could occur in the middle of a coding sequence compromising the gene

53. Large-scale mutations
Trinucleotide repeat expansion
Increases number of repeats in genetic code
CAG CAG CAG CAG CAG CAG CAG CAG
Huntingtons disease

54. Causes of genetic mutations
Spontaneous mutations
Inaccurate DNA replication
Induced mutations
Caused by environmental agent – mutagen
Directly alter DNA – entering cell nucleus
Chemicals, radiation

55. Chemical Mutagens Modify individual nucleotides
Nucleotides resemble other base pairs
Confuses replication machinery – inaccurate copying
Nitrous acid
Mimicking DNA nucleotides
Ethidium bromide – insert itself into DNA

56. Radiation - Low energy UV B rays Non-homologous end joining
Bonds form between adjacent nucleotides along DNA strand
Form kinks in backbone
Skin cancer

57. Radiation – high energy
Ionizing radiation – x-ray, gamma rays
Strip molecules of electrons
Break bonds within DNA
Delete portions of chromosomes
Development of tumors

58. Mutation in prokaryotes
DNA is mostly coding sequences
Mutation is harmful – superbugs

59. Genomes and Gene organization
Human Body
22 autosomal chromosomes
1 pair of each sex chromosome (XX, YY)

60. Genomes and Gene organization
Components
VNTR’s–variable number tandem repeats (microsatellites)
Sequences of long repeating base pairs
TAGTAGTAGTAGTAG
LINEs – long interspersed nuclear elements
SINEs – short interspersed nuclear elements
Transposons – small sequences of DNA that move about the genome and insert themselves into different chromosomes
Pseudogene – code is similar to gene but is unable to code for protein

61. Viruses Not alive but can replicate themselves Contain DNA or RNA
Capsid – protein coat
Envelope – cell membrane

62. Virus
4000 species of virus have been classified

63. replication DNA RNA (retrovirus) Transcription and translation
Uses reverse transcriptase – enzyme
Uses cells parts to make a single strand of DNA and then makes a complementary strand from that copy
Integrase – incorporates into our genetic code

65. Virus as Vectors Transduction
Using a virus vector to insert DNA into a cell or bacterium