1. Gene Expression
Ch 11

2. Gene expression Genes to proteins
Genotype to phenotype
Produce specific proteins when and where they are needed

3. lac Operon E. Coli make enzymes to utilize lactose sugars
Dependent on presence/absence of lactose
3 enzymes to take up and metabolize lactose
Genes that code for enzymes located next to each other in DNA

4. Lactose-utilization genes
Fig. 11-1b
OPERON
Regulatory
gene
Promoter Operator
Lactose-utilization genes
DNA
mRNA
RNA polymerase
cannot attach to
promoter
Active
repressor
Protein
Operon turned off (lactose absent)
DNA
RNA polymerase
bound to promoter
mRNA
Protein
Enzymes for lactose utilization
Lactose
Inactive
repressor
Operon turned on (lactose inactivates repressor)

5. lac Operon Control sequence Operon Promoter Operator
Genes, promoter and Operator
***Exist almost solely in prokaryotes

6. lac Operon Repressors Block RNA polymerase from binding
Regulatory genes code for repressors
Located outside the operon

7. Lactose-utilization genes
Fig. 11-1b
OPERON
Regulatory
gene
Promoter Operator
Lactose-utilization genes
DNA
mRNA
RNA polymerase
cannot attach to
promoter
Active
repressor
Protein
Operon turned off (lactose absent)
DNA
RNA polymerase
bound to promoter
mRNA
Protein
Enzymes for lactose utilization
Lactose
Inactive
repressor
Operon turned on (lactose inactivates repressor)

8. Trp Operon
trp operon
repressor is inactive alone
When tryptophan present, binds to repressor, enabling it to switch transcription off

9. Promoter Operator Gene DNA Active repressor Active repressor
Fig. 11-1c
Promoter
Operator
Gene
DNA
Active
repressor
Active
repressor
Tryptophan
Inactive
repressor
Inactive
repressor
Lactose
lac operon
trp operon

10. Differentiation Specialized in structure and function
Results from selective gene expression
Variety of cell types, expressing different combination of genes

11. Cell division in culture
Differentiation
Differentiated cells may retain all of their genetic potential
Most differentiated cells retain a complete set of genes
Root of carrot plant
Root cells cultured in nutrient medium
Cell division in culture
Plantlet
Adult Plant
Single cell
Figure 11.3

12. The Chromosome Packaging helps regulate expression Histone proteins
Aid in packaging and ordering DNA
DNA double helix (2-nm diameter)
Histones
Linker
“Beads on a string”
Nucleosome (10-nm diameter)
Tight helical fiber (30-nm diameter)
Supercoil
(300-nm diameter)
Metaphase chromosome
700 nm
TEM

13. The Chromosome Nucleosome
DNA-histone complex involving DNA wound around 8 histone protein core
Resembles beads on a string
Linkers
Join consecutive nucleosomes
Packing presumably prevents access of transcription proteins
DNA double helix (2-nm diameter)
Histones
Linker
“Beads on a string”
Nucleosome (10-nm diameter)
Tight helical fiber (30-nm diameter)
Supercoil
(300-nm diameter)
Metaphase chromosome
700 nm
TEM

14. Proteins controlling transcription
Regulatory proteins turn off/on gene transcription
Transcription factors
Enhancers
Silencers
RNA splicing
Enhancers
Promoter
Gene
DNA
Activator proteins
Other proteins
Transcription factors
RNA polymerase
Bending of DNA
Transcription
Figure 11.6

15. Proteins controlling transcription
Enhancers
Activators bind and bend DNA
Interact with other transcription factor proteins
Bind as complex to promoter
Silencers
RNA splicing
Enhancers
Promoter
Gene
DNA
Activator proteins
Other proteins
Transcription factors
RNA polymerase
Bending of DNA
Transcription
Figure 11.6

16. Proteins controlling transcription
Silencers
Bind to DNA and inhibit start of transcription
Enhancers
Promoter
Gene
DNA
Activator proteins
Other proteins
Transcription factors
RNA polymerase
Bending of DNA
Transcription
Figure 11.6

17. Splicing Alternate RNA splicing Splicing can occur in more than 1 way
Different mRNA from same RNA transcript
DNA
RNA
transcript
mRNA
Exons or
RNA splicing
Figure 11.7

18. Small RNA’s miRNA RNA interference 1 Protein miRNA miRNA- protein
complex 2
Target mRNA 4 3
mRNA degraded OR
Translation blocked

19. Regulation of translation
Breakdown of mRNA
Initiation of translation
Protein activation
Protein breakdown
Folding of
polypeptide and
formation of
S—S linkages
Cleavage
Initial polypeptide
(inactive)
Folded polypeptide
(inactive)

20. Cascades Protein products from one set of genes activate another set
Egg cell
Egg cell
within ovarian
follicle
Protein
signal
Protein products from one set of genes activate another set
Homeotic gene
Follicle cells
Gene expression 1
“Head”
mRNA
Cascades of
gene expression 2
Embryo
Body
segments 3
Gene expression
Adult fly 4

21. Signal transduction pathways
Signaling cell
Signal molecule
Series of molecular changes that converts signal on cell surface to specific response inside cell
Receptor protein
Plasma membrane 1 2 3
Target cell
Relay proteins
Transcription factor (activated) 4
Nucleus
DNA 5
mRNA
Transcription
New protein 6
Translation
Figure 11.14

22. Cloning
A clone is an individual created by asexual reproduction and thus is genetically identical to a single parent

23. Cloning Regeneration Nuclear Transplantation
Reproductive and Therapeutic cloning
Remove nucleus from egg cell
Add somatic cell
from adult donor
Grow in culture to produce an
early embryo (blastocyst)
Implant blastocyst in surrogate mother
Remove embryonic stem cells from blastocyst and grow in culture
Induce stem cells to form specialized cells (therapeutic cloning)
Clone of donor is born
(reproductive cloning)
Donor cell
Nucleus from donor cell
Figure 11.10

24. Reproductive Cloning Clone grown into new individual Not exact copy
Behavioral differences
Ethical questions

25. Therapeutic Cloning Medical potential Embryonic stem cells
Adult stem cells
Replace non-reproducing specialized cells as needed
Only give rise to certain tissues
Obtaining differentiated cells for cell replacement therapy
Tissue taken from patient, nucleus from one of the cells implanted into donor oocyte without nucleus. Resulting egg is allowed to develop into early embryo and ES cells are harvested and grown and in culture. Induced to differentiate and transplanted to patient.

26. Cancer Divide uncontrollably Oncogene
Mutations whose protein products affect the cell cycle
Oncogene
Can cause cancer when present in a single copy

27. Cancer Proto-oncogene Gene that has potential to become oncogene
Mutation or virus
Proto-oncogene DNA
Mutation within the gene
Multiple copies of the gene
Gene moved to new DNA locus, under new controls
Oncogene
New promoter
Hyperactive growth- stimulating protein in normal amount
Normal growth- stimulating protein in excess
Figure 11.16A

28. Cancer Tumor-suppressor genes Help prevent uncontrolled growth
Mutated tumor-suppressor gene
Normal growth- inhibiting protein
Cell division under control
Defective, nonfunctioning protein
Cell division not under control
Figure 11.16B

29. Oncogene proteins and faulty tumor-suppressor proteins can interfere with normal signal transduction pathways
Growth-inhibiting factor
Receptor
Nonfunctional transcription factor (product of faulty p53 tumor-suppressor gene)
Relay proteins
Transcription factor (activated)
Transcription
Translation
Protein that inhibits cell division
cannot trigger transcription
Protein absent (cell division not inhibited)
Normal product
of p53 gene
Figure 11.17B
Growth factor
Target cell
Receptor
Hyperactive relay protein (product of ras oncogene) issues signals on its own
Normal product of ras gene
Relay proteins
Transcription factor (activated)
DNA
Nucleus
Transcription
Translation
Protein that stimulates cell division
Figure 11.17A

30. Cancer Series of genetic changes Colon cancer 1 2 3 Colon wall
Increased cell division
Oncogene activated 2
Growth of polyp
Tumor-suppressor gene inactivated 3
Growth of malignant tumor (carcinoma)
Second tumor- suppressor gene inactivated
Cellular changes:
DNA changes:

31. Cancer Series of mutations Chromosomes mutation 1 2 3 4 mutations
Normal cell
Malignant cell
Figure 11.18B

32. Table 11.20

33. Videos
Lac Operon
RNA Splicing