regulation of gene action - university of...
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Regulation of Gene Action
The basis of cell differentiation is generegulation: different sets of genes are turned onand off in different cells. (There are othermechanisms as well but this is our focus.)
E.g. globin genes are expressed only inerythroblasts and are turned off in muscle cells.Myosin genes are on in muscle cells but off inerythrocytes.
Progression through the cell cycle also requiresturning different sets of genes on and off atdifferent stages.
Bacteria and single-celled eukaryotes undergocell differentiation. This includes respondingto the availability of different nutrients.
I will discuss some of the most basic aspects;Dr. Restifo will give more detail.
Levels of Expression and Control
The expression of any genebegins with transcriptionwhich can be regulated. Theexpression of protein-codinggenes requires severaladditional steps and can beturned off at any step.However, I will focus only onthe control of transcription.
DNA
mRNA
Polypeptide
Protein
transcriptionmRNA stability
translation(ribosomes,tRNAs, aminoacids, etc.)
foldingstabilityaggregationlocalization
Transcription Control in ProkaryotesNegative Regulation
Negative regulationinvolves a proteinrepressor that binds to arepressor binding siteand prevents binding ofthe transcriptioncomplex.
Inducible system: offunless inducermolecule binds to andinactivates repressor.
Repressible system: onunless co-repressorbinds to inactiveaporepressor to formactive repressor.
Negative Regulation Examples
Inducible system: lactose operon in E. coli
E. coli can cleave lactose into glucose + galactose to use forcarbon and energy sources. This requires the enzyme β-galactosidase, and also galactoside permease to import the lactoseinto the cell.
If there is no lactose in the medium, E. coli does not make eitherβ-galactosidase or galactoside permease. Synthesis is blocked atthe transcription level. If lactose is added to the medium, thesynthesis of both molecules is induced.
lac OperonOperon encodes• lacZ: β-galactosidase which cleaves lactose
into glucose and galactose.• lacY: lactose permease which brings lactose
into the cell• lacA: thiogalactoside transacetylase, not
required for growth on lactose, unknownfunction but sequence is conserved so it isimportant.
Other important players:• lacP: Promoter, binds RNA polymerase to
start transcription• lacO: Operator, binds repressor• lacI: Repressor gene, encodes repressor
protein
β-galactosidase and lactose permease are madeonly if lactose is present; only if they areneeded.They are induced by their substrate.
Basic features of lac operon were deduced from mutant phenotypes byFrancois Jacob, Jacques Monod, and collaborators in 1960s by studying thephenotypes of mutants.
lac Operon Mutants
Francois Jacob, Jacques Monod, Andre LwoffNobel Prize 1965
“Commandant Malivert”of the Resistance, Legion ofHonor
Jacob in medicalbattalion in NorthAfrica, wounded inaction
lac Operon Mutants
Repressor can’t bind inducer;super-repressorlacI s
Promoter can’t bind RNApolymerase; operon not
transcribedlacP -
lacO can’t bind repressor;constitutive (always on)lacO c
Null mutation in lacYlacY -
Null mutation in lacZlacZ -
NatureGenotype
Studied the interactions of different mutant alleles in partial diploidswhich have the bacterial chromosome plus a plasmid with some genes.Plasmids = small DNA molecules that use their own replication origins toreplicate independently of the cell chromosome; have the own origin ofreplication. Usually not required for cell function; some may be present inmany copies.
Studying Interactions of lac Operon Mutants
ChromosomeF’ lac plasmid
lac operonlacZ + lacY -
lac operonlacZ - lacY +
Cell genotype F’ lacZ - lacY + / lacZ + lacY - Cell phenotype Lac + (NOTE: other genes assumed to be wild type if not specified.)
(DNA molecules notto scale)
Phenotypes of lac Operon Mutants in Diploids
Jacob, Monod, and collaborators deduced how the lac operon is controlled from these dataand from the map position of the mutants. Note lacO and lacP mutants only affect expressionof lac genes on the same chromosome, while lacI mutants can operate at a distance, fromanother chromosome.
lac Operon: Second Level of Regulation(Things are always more complicated than we’d like.)
When glucose is present, β-galactosidase etc. are notmade.
cAMP = cyclic AMPCRP = cAMP receptorprotein
Glucose inhibits synthesisof cAMP.
cAMP+CRP must bebound to promoter in orderfor lac transcription
Negative Regulation Examples
Inducible lac operon: operon turned ononly when lactose is available as acarbon and nitrogen source.
Repressible system: tryptophanoperon in E. coli
Tryptophan is needed all the time bygrowing cells, so trp genes should be onall the time, until cells have madesufficient tryptophan (or it is providedin the medium).
Chorismic acid
Anthranilic acid
PRA
CDRP
InGP
Indole
L-Tryptophan
ASase trpE
PRTase trpD
InGPSase trpC
TSaseB trpB
TSaseA trpA
Negative Regulation ExamplesRepressible system: tryptophan operon in E. coli
Tryptophan is needed all the time by growing cells, so trp genes should be on all thetime, until cells have made sufficient tryptophan.
trpA-E genes are in an operon. OK if only needed to make tryptophan.Has operator trp o and promoter trp-p and attenuator trp a.
Negative Regulation of trp Operon
Tryptophan levels low:aporepresssor proteincomplex (encoded by distantgenes) can’t bind topromoter and transcriptionis on.
Tryptophan levels high:tryptophan binds toaporepressor to form activerepressor which binds topromoter and shuts offtranscription.
Attenuation mechanismstops transcription in leaderregion unless there issufficient Trp-tRNA in thecell, provides fine-tuning oftryptophan synthesis.