View
223
Download
0
Category
Tags:
Preview:
Citation preview
Chapter 11
Regulation of Gene Expression
11.1 Several Strategies Are Used to Regulate Gene Expression
• Gene expression is precisely regulated
• Constitutive genes-are actively expressed all the time
• Inducible genes-are expressed only when their proteins are needed by the cell
• We will focus on inducible genes
Genes are subject to positive and negative regulation
• DNA can be regulated at every step from genes to proteins
• During transcription there is an important form of gene regulation
• Genes that get transcribed are said to be active
Differential gene expression: expression of different genes in different kinds of cells, despite having the same genome
• Two types of transcription factors (proteins) control whether or not a gene is active– Repressors– Activators
• These bind to specific DNA sequences at or near the promoter and decide which genes to be transcribed
• In negative regulation, a repressor binds near the promoter to prevent transcription
• In positive regulation, the binding of an activator stimulates transcription
http://www.sciencedirect.com/science/article/pii/S002555641200003X
11.2 Many prokaryotic genes are regulated in Operons
• Prokaryotes conserve E by making proteins only when needed
• The most efficient means of regulating gene expression is at the level of transcription
Regulating gene transcription
• Inducible genes expression is switched on by an inducer
• Example: prokaryotic bacteria do not create lactase if allactose (lactose) is not present. When allactose (inducer) is present the bacterial cell begins creating the protein lactase to metabolize the lactose (done with three proteins)
Lac Operon
http://missbakersbiologyclass.com/blog/2010/05/03/themes-in-biology-regulation/
Operons are units of transcriptional regulation in prokaryotes
• Structural genes-a gene that encodes the primary structure of a protein not involved in the regulation of gene expression (example three genes that metabolize lactose)
• A cluster of genes with a single promoter is called an operon and the operon that codes for the three-lactose metabolizing enzymes is called the lac operon
Lac Operon
http://missbakersbiologyclass.com/blog/2010/05/03/themes-in-biology-regulation/
• The lac operon had another DNA sequence called an operator, which is near the promoter and controls transcription of the structural genes
• The repressor proteins can bind very tightly with the operator– An inducible operon is turned off unless
needed– A repressible operon is turned on unless not
needed
Lac Operon
http://missbakersbiologyclass.com/blog/2010/05/03/themes-in-biology-regulation/
Operator-repressor interactions regulate transcription in the lac and trp operons
• In inducible lac operons, a repressor protein prevents transcription until the lac-encoded proteins are needed
• The trp operon is a repressible operon that is turned off by a repressor only under some circumstances
Lac Operon
• The lac operon is not transcribed unless lactose is the main sugar present
• A repressor protein is normally bound to the operator, preventing transcription
• When lactose is present it detaches from the operator which allows RNA polymerase to bind to the promoter and transcribe the structural genes
http://www.google.com/imgres?q=operon&hl=en&safe=active&tbo=d&biw=1024&bih=566&tbm=isch&tbnid=_EqT6omOTQGqLM:&imgrefurl=http://www.tumblr.com/tagged/lac-operon&docid=eJT3XNPJ7cWwxM&imgurl=http://media.tumblr.com/tumblr_m6k1ewci511qcih5l.gif&w=500&h=499&ei=Nym9UJvEMMvHqQGwroGoBQ&zoom=1&iact=hc&vpx=658&vpy=99&dur=3108&hovh=224&hovw=225&tx=112&ty=144&sig=101186996142079840199&page=1&tbnh=111&tbnw=111&start=0&ndsp=19&ved=1t:429,r:5,s:0,i:99
• The key to this system is the repressor protein
• The repressor is always present in the cell to occupy the operator and keep the operon turned off
• Has a sport for the inducer to bind and when it binds allosteric regulation happens
Repressor
http://en.wikipedia.org/wiki/Repressor
trp Operon
• A repressible operon is switched off when its repressor is bound to its operator
• In this case the repressor binds to the DNA only if a co-repressor is present
• Co-repressor-a molecule that binds to the repressor which causes it to bind to the operator and inhibit transcription
trp operon
http://en.wikipedia.org/wiki/Trp_operon
• The trp operon’s structural genes catalyze the synthesis of the amino acid tryptophan and is a repressible operon
• In high concentrations the cell wants to stop making the enzymes to create trp
• Trp functions as a co-repressor that binds to the repressor of the trp operon and prevent transcription
trp operon
http://en.wikipedia.org/wiki/Trp_operon
Summarize the differences between operons
• Inducible: the inducer interacts with the repressor which causes it to not bind to the operator and halts transcription
• Repressible: the product of the pathway which is the co-repressor binds to the repressor which then binds to the operator and halts transcription
Lac Operon
http://missbakersbiologyclass.com/blog/2010/05/03/themes-in-biology-regulation/
trp operon
http://en.wikipedia.org/wiki/Trp_operon
RNA polymerase can be directed to a class of promoters
• Sigma factors-proteins in prokaryotes that can bind to RNA polymerase and direct the polymerase to specific promoters
• Example: when nutrients run out for bacteria the cell goes into a sporulation lifestyle and is dormant for a while. These genes are only created when directed by sigma factors
11.3 Eukaryotic Genes Are Regulated by Transcription Factors and DNA Changes
Transcription factors act at eukaryotic promoters
• A eukaryotic promoter is a region of DNA where RNA polymerase binds
• The most common promoter is the TATA box because it has a lot of A-T base pairs
• RNA P cannot bind to the promoter unless it has general transcription factors bind to the promoter first
General Transcription Factors
http://www.mun.ca/biology/desmid/brian/BIOL3530/DB_Ch09/DBNDiff.html
• First, the protein TFIID binds to the TATA box which changes the shape of the DNA so other TF’s can bind
• The RNA P then binds after other TF’s have bound to the DNA
• These TF’s may be positive regulators (activators) or negative regulators (repressors) of transcription
General Transcription Factors
http://www.mun.ca/biology/desmid/brian/BIOL3530/DB_Ch09/DBNDiff.html
• DNA sequences that binds activators are called enhancers, those that bind repressors are called silencers
• When these bind to DNA sequences they interact with the RNA P complex and cause the DNA to bend
• The combination of factors present determines the initiation of transcription
• (2,000 different TF’s in humans so many different regulation possibilities)
Initiation of transcription
• Example of Activation
The expression of sets of genes can be coordinately regulated by transcription factors
• Eukaryotes also use sigma factors to guide the RNA P to specific promoters
• The expression of genes can be coordinated if they share regulatory sequences that bind the same transcription factors
• Example in book lets read… (pg 217)
Epigenetic changes to DNA and chromatin can regulate transcription
• Euk- can also regulate the transcription of large stretches of DNA
• Do this by altering the DNA or the chromosomal proteins that package the DNA (this is reversible unlike mutations)
• These are called epigenetic changes and can be passed on to daughter cells after mitosis or meiosis
Proteins that package the DNA
DNA methylation
• Cytosine residues in the DNA are chemically modified by the addition of a methyl group (-CH3) to make 5-methyl cytosine
• This is done by the enzyme DNA methyltransferase
• Usually done to C’s that are adjacent to G’s
• Areas that have a lot of the are called CpG Islands
• This change is heritable and reversible
• The methyl group can be removed by an enzyme named demethylase
• Methylated DNA binds proteins that repress transcription so the gene may be silenced
• Sometimes large stretches or whole chromosome can be Methylated
• Euchromatin is transcribed and heterochromatin is Methylated and not transcribed
DNA methylation: represses transcription by condensing DNA
--For example, Barr bodies (inactivated X chromosomes in females) often have methylated DNA
Female bar body example… lets read page 219
Histone Protein Modification
• Another mechanism for epigenetic gene regulation is the alteration of chromatin structure or chromatin remodeling
• DNA is packaged as a nucleosome which is a core of positively charged histone proteins that DNA is wound around
• Nucleosomes make it so RNA P cannot bind
• Each histone has a tail of amino acids that sticks out of the structure
• Enzymes called histone acetyltransferases add acetyl groups to these positively charged amino acids which neutralizes their charges
• Usually there is a strong attraction between the proteins and DNA which is negatively charged
• This then loosens the nucleosome and allows for transcription
Histone modifications:acetylation promotes transcription due to neutralization of positive charges so they don’t bind to neighboring nucleosomes(I remember “acetylation= activation”)
• Acetyltransferases can activate transcription
• Another chromatin remodeling protein histone deacetylase removes acetyl groups from histones and represses transcription
• Histone protein modification video
Epigenetic changes can be induced by the environment
• Epigenetic changes can be passed on to the next generation if done in a germline cell
• Epigenetic genomes have been proven to be different by twin studies
• Stress can be a factor for methylation
11.4 Eukaryotic Gene Expression Can be Regulated after Transcription
• So far we have only talked about gene regulate before transcription, What about after…
Different mRNA’s can be made from the same gene by alternative splicing
• Most mRNA in eukaryotes have several introns
• If an exon were to be spliced out when two intons are cut this would create an new protein
• This is called alternative splicing and is a deliberate way to create alternative proteins from a single gene
Alternative RNA splicing: allows different RNA molecules (and thus, different proteins) to be produced from same primary transcript (pre-mRNA)
Examples on page 221…
• Before the human genome was sequenced…scientists believed there were 80,000 to 150,000 protein coding genes
• They now know there are 24,000 genes
• 80 percent of this variation are due to alternative splicing
• Example with humans and chimpanzees
Let’s review the kinds of RNA we’ve encountered so far:
• mRNA• tRNA• rRNA• snRNP
And let’s add:• miRNA (micro RNA)(also known as RNAi) (Fire
& Mello, Nobel Prize 2006)• siRNA (small interfering RNA)
MicroRNAs are important regulators of gene expression
• Only a fraction of genes code for proteins
• Biologists used to think that the rest of the genome was not transcribed and they called it “junk” DNA
• They now know that some of it is transcribed into very small RNA molecules called microRNA (miRNA)
• These usually code for genes that turn on or off gene expression (example page 222)
mRNA degradation
–Nova clip RNAi
• The microRNA targets a mRNA and inhibits its translation
• It than degrades the target mRNA
• This is a gene silencing mechanism
Translation of mRNA can be regulated
• For most genes mRNA doesn’t necessarily relate to the number of proteins
• A lot of mRNA doesn’t necessarily mean a lot of protein or vice versa
• Cells regulate how many proteins get made after transcription in 2 ways:– Regulation the translation of mRNA– Altering how long proteins persist in the cell
3 ways in which translation can be regulated (examples page 223)
• 1. Inhibition of translation with miRNAs
• 2. Modification of the 5’ cap– An mRNA that is capped with an unmodified
GTP molecule is not translated
• 3. Translational repressor proteins– Block translation by binding to mRNAs and
preventing their attachment to the ribosome– Known as translational repressors
Protein stability can be regulated
• Protein content is a result of both protein synthesis and protein degradation
• Proteins can be targeted for destruction in a chain of events that begins when an enzyme attaches a protein called ubiquitin
• Other ubiquitins then attach to the primary one forming a polyubiquitin
• The polyubiquitin then binds to a protein complex called a proteasome
• This then unfolds the protein inside of it
• Example the breakdown of cyclins during the cell cycle
• This needs to be done at the correct time and it is done by proteasomes
Cyclin-dependent kinase,
phosphorylates substrate proteins
Maturation-promoting factor (or M-phase PF)
Recommended