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Bonus #1 is due 10/02
More Regulating Gene Expression
Combinations of 3 nucleotides code for each 1 amino acid in a protein.
We looked at the mechanisms of gene expression, now we will look at its regulation.
Why change gene expression?
•Different cells need different components•Responding to the environment•Replacement of damaged/worn-out parts
Fig 15.1
Two points to keep in mind:
1. Cellular components are constantly turned-over.
2. Gene expression takes time:Typically more than an
hour from DNA to protein. Most rapidly 15 minutes.
Fig 15.1
•Gene expression can be controlled at many points between DNA and making the final proteins.
•Changes in the various steps of gene expression control when and how much of a product are produced.
Fig 15.1
In bacteria, transcription and translation occur simultaneously. So most regulation of gene expression happens at transcription.
Fig 13.22
Transcription initiation in prokaryotes:sigma factor binds to the -35 and -10 regions and then the RNA polymerase subunits bind and begin transcription
Fig 12.7
Fig 14.3
Operon: several genes whose expression is controlled by the same promoter
Fig 14.3E. coli lactose metabolism
Fig 14.4 In the absence of lactose, the lac operon is repressed.
Fig 14.4 Lactose binds to the repressor, making it inactive, so that transcription can occur.
Fig 14.5
Repression or induction of the lac operon
Fig 14.3 There is more to lac gene expression than repression
Fig 14.8 Glucose is a better energy source than lactose
Fig 14.8 Low glucose leads to high cAMP
cAMP binds to CAP which increases lac operon transcription
Fig 14.8High glucose leads to low cAMP
low cAMP, CAP inactive, low lac operon transcription
Fig 14.3
The lac operon: one example of regulating gene expression in bacteria
Overview of transcriptional regulation
Fig 14.1 and 15.1
Fig 16.1
Gene Expression is controlled at all of these steps:•DNA packaging•Transcription•RNA processing and transport•RNA degradation•Translation•Post-translational
Fig 15.1
Fig 16.1
Gene Expression is controlled at all of these steps:•DNA packaging•Transcription•RNA processing and transport•RNA degradation•Translation•Post-translational
Fig 15.1
Tightly packaged DNA is unavailable. DNA packaging changes as the need for different genes changes.
Fig 10.21
Different levels of DNA packaging Fig 10.21
Histones can be post-translationally modified, which affects their abililty to bind DNA.
Acetylation (-COCH3): post-translational modifications of the histones loosen DNA binding
Fig 12.15
Acetylation of histones (-COCH3) causes a loosening of the DNA/histone bond…unpackaging the DNA.
Fig 15.13DNA methylation
Fig 15.14
DNA methylation often inhibits transcription
Fig 15.15Epigenetics:the inheritance of DNA modifications, including methylaton
Four-stranded DNA: cancer, gene regulation and drug developmentby Julian Leon HuppertPhilosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering SciencesTriennial Issue of 'Chemistry and Engineering’DOI: 10.1098/rsta.2007.0011Published: September 13, 2007
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
4 strand DNA Fig 1
Four-stranded DNA forms between sequences of guanines…G-quadruplexes
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
4 strand DNA Fig 1
Four-stranded DNA forms between sequences of guanines…G-quadruplexes
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
4 strand DNA Fig 2
The G-quadruplexes can form from 4, 2, or 1 DNA strand.
Fig 10.11
During DNA replication, the ends of the DNA are not completely copied.
Telomeres are non-gene DNA at the ends of DNA strands.
Telomeres are shortened during DNA replication.
Fig 10.11
Fig 11.25
Telomeres can be lengthened by telomerase.
The telomeric cap structure is one place where G-quadruplexes can be found
Telomeres are non-gene DNA at the ends of DNA strands.
Short telomeres will cause cells to stop replicating or cell death.
The critical size is unknown.
Fig 10.11
Drugs that can block the action of telomerase, by binding the G-quadruplexes, are being
investigated to treat cancer.
Fig 12.13
Eukaryotic promoters often contain G-rich areas
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
4 strand DNA Fig 5
G-quadruplex in promoters
If the promoter is defined as 1 kbase upstream of the transcription start site:•Quadruplex motifs are significantly overrepresented relative to the rest of the genome, by almost an order of magnitude.
•almost half of all known genes have a putative quadruplex-forming motif
•By comparison, the TATA box motif—probably the best-known regulatory motif and a staple of undergraduate textbooks—is found in only approximately 10% of genes.Four-stranded DNA: cancer, gene regulation and drug development by Julian Leon Huppert in Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences Triennial Issue of 'Chemistry and Engineering’ DOI: 10.1098/rsta.2007.0011 Published: September 13, 2007
Four-stranded DNA: cancer, gene regulation and drug development by Julian Leon Huppert in Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences Triennial Issue of 'Chemistry and Engineering’ DOI: 10.1098/rsta.2007.0011 Published: September 13, 2007
Oncogenes, the genes involved in cancer, are especially rich in potentially regulatory quadruplexes—69% of them have such motifs
G-quadruplex ligands
G-quadruplex
BRACO-19
TMPyP4
telomestatin
4 strandDNAFig 6
Down regulates telomerase and some oncogene transcription
Specifically binds to telomeres, naturally occurring in Streptomyces anulatus
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
4 strand DNA Fig 7
Model of specific G-quadruplex ligand binding to G-quadruplex and a specific DNA sequence
Fig 16.1
Gene Expression is controlled at all of these steps:•DNA packaging•Transcription•RNA processing and transport•RNA degradation•Translation•Post-translational
Fig 15.1
Bonus #1 is due 10/02
More Regulating Gene Expression