Post on 02-Jan-2016
Chapter 8
Control of Gene Expression
EssentialCell Biology
FOURTH EDITION
Copyright © Garland Science 2014
Alberts • Bray • Hopkin • Johnson • Lewis • Raff • Roberts • Walter
Fig. 8-1
The vast differences in size and morphology of differentcell types is due to differences in gene expression from the same genome.
β cells of pancreas: insulinα cells of pancreas: glucagonB cells: antibodiesRBC: hemoglobinskeletal muscle: muscle actin and myosinneuron: neurotransmitters/receptorsliver: gluconeogenesis enzymes, signaling proteins
Deprogramming of terminally differentiated cells shows that all cells of a multi-cellular organism contain a full genome.
even mammals!
Fig. 8-2
Gene expression can be controlled at many levels.
Fig. 8-3
*
Transcription regulators bind specific DNA sequences
through interaction with the major groove.
Fig. 8-4 amino acids H bond with nitrogenous bases
Our earliest knowledge of transcriptional regulation came from studies in bacteria.
Bacteria have genes of related function transcribed from a single promoter.
Fig. 8-6
Translational Repressor Allosterically Regulated
product of genes activates the repressor when level in medium high
Fig. 8-7
Translational Activator Also Allosterically Regulated
cAMP signaling molecule activates the activator when level high in cell
Fig. 8-7
cAMP
CAP
Lac operon has binding sites for both an activator and a repressor.
active when lactose absent
active when lactose absentactive when
glucose absent
active when glucose absent
active when lactose absent
Activator Repressor
inactive when glucose present
inactive when glucose present
inactive when lactose present
Fig. 8-9
In eukaryotes, activators and repressors can work from a distance.
Fig. 8-10
Mediator links to preinitiation complex through DNA bending
Some activators act through altering chromatin.
Fig. 8-11
making TATA box available to TBP
Animation (0:30)
Activators and Repressors Act By Committee: Combinatorial Control
Fig. 8-12
Example of Combinatorial Control: Drosophila Embryo
Fig. 8-12
Each regulatory segment specifies particular stripe
promoter-reporter gene fusionmade by recombinant DNA technology
Each regulatory segment provides binding sites for a different set of regulatory proteins.
stripe too broad when lacking these
stripe too weak when lacking theseFig. 8-14
Specific combinations of regulatory proteins induce specific cell fates from precursor cells.
Fig. 8-12
Example: Introduction of neuron-specific regulators into liver cell induces differentiation into neuron!
Fig. 8-16
Example: Introduction of Embryonic Stem (ES) cell-specific regulators into fibroblast induces differentiation into ES-like cell(induced Pluripotent Stem cell)!
Fig. 8-18
have potential for gene therapy
A single regulatory protein can evendirect developmentof entire organ
Ey regulator expressionin leg precursor resultsin eye development in Drosophila leg!
Fig. 8-19
Cells have memory mechanisms that allow them to record a decision made after ceasing expression of a regulatory protein expressed only during early embryogenesis.
1) Feedback Loop2) DNA methylation3) Histone modification
Cell-Memory Mechanisms
Type 1) Feedback Loop
Fig. 8-20
regulatory protein regulates its own
transcription
Type 2) DNA Methylation
(Cytosine of CG dinucleotide)
Fig. 8-21, 22
Type 3) Histone Modification
Fig. 8-23 Heterochromatin proteins recruit histone modificationenzyme needed for their binding
Examples of Translational Control in Bacteria
Ribosomal proteins inhibit their L. monocytogenes mRNA containsown translation when in excess thermosensing sequence
Fig. 8-24
The genome sequencing projects and studies in model organisms have revealed the presence of many functional RNAs that are non-coding (ncRNAs)
1) micro RNAs (miRNAs)2) small interfering (siRNAs)3) long non-coding RNAs (lncRNAs)
At least one third of human protein-coding genes are regulated by miRNAs.
Fig. 8-25
RISC also targets dsRNAs from foreign transpososon and viral DNA
Fig. 8-2
In lower eukaryotes, RISC also recruits heterochromatin proteins to silence foreign DNA.
Fig. 5-30
Heterochromatin is a Heritable Inactive Chromatin State
Random expression of Xist ncRNA from Xp selects it for inactivation
Xist RNA recruits histonemodifying enzyme andHP1-like protein
Xm has equal chance of being selected
Clonal pattern of X inactivation responsible for coat pattern of calico cats