Gene Regulation Lecture Slides - Fall 24

Summary

These lecture slides cover various aspects of gene regulation, including constitutive, coordinate, and post-transcriptional mechanisms. They examine the roles of different elements in gene regulation, including transcription factors and mRNA modifications. The slides also touch upon the significance of gene regulation in human health and disease.

Full Transcript

Gene Regulation: A
Continuation of a
Complicated Story…
BMS 532
BLOCK 4 LECTURE 2
 Objectives
1. Define the following terms or phrases: constitutive, coordinate regulation, operator, promoter, regulatory element, regulatory protein,
inducible, repressible, aporepressor, iron response element, and attenuation
2. Explain the role of gene regulation in cellular and organismal function with particular emphasis on the post-transcriptional activities and
their impact on human health
3. Identify the various levels where regulation can take place and assess outcomes for changes in regulation
4. Explain the concept of gene regulatory networks and the role understanding these networks plays in human genetics
5. Summarize an example of an RNA modification and assess the consequences for changes in RNA regulation or processing on the
product generated or its availability
6. Explain the concept of functional heterogeneity and the role of gene expression in conferring heterogeneity in populations of cells
7. Summarize the features of the lac and trp operons including regulation, genes contained, and activity
8. Compare and contrast the lac and trp operons with emphasis on their structures and regulation
9. Compare and contrast transcriptional and translational regulation
10. Explain the role for IRES and iron response elements in translational regulation in eukaryotes with emphasis on how iron deficiency can
influence translation
11. Determine the consequence for gene expression (increase, decrease, no change) for environmental conditions as well as DNA mutation
with an emphasis on promoters, operators, other regulatory elements, and regulatory proteins
LO1, LO2

Reminder…
Gene regulation = the process through which levels of gene
expression varies under different conditions
◦ Control of gene activity to increase or decrease expression as needed

Genes that are unregulated = expressed at all times =
Constitutive
◦ Tend to encode for things needed at all times for survival

Can be at multiple levels
◦ Transcriptional regulation: most common
◦ Regulate association of polymerase with promoter
◦ Translational regulation
LO1, LO2

Post-transcriptional Regulation and
Human Disease
Errors in post-transcript processing can result
in a wide range of tissue-specific disease
consequences
Areas implicated include:
◦ Processing of mRNA
◦ mRNA export
◦ Localization of mRNA/Assembly of key RNAs
◦ Translation
◦ Turnover/Decay
LO1, LO2,
LO3, LO9

Gene Expression as a “Pathway”
Although gene expression traditionally refers to transcription exclusively, we can view the overall
regulation of material in the cell as a pathway of control for functionality
Eukaryotes use transcription as the main mechanism for regulation, however, there are multiple
additional controls in place
◦ Processing
◦ Translation
◦ Post-translational modification
LO4

Gene Regulatory Networks
Collection of regulatory relationships between transcription factors and specific mRNA-binding sites
◦ Control both gene expression levels and protein synthesis
◦ microRNAs alongside transcription factors (TFs) = gene regulation
◦ TFs also regulate microRNA production

Large scale gene expression data helps to decipher the complex relationships between gene
expression and the corresponding regulation of that expression
◦ TFs can be grouped into families based on their DNA-binding domain(s)
◦ Several improvements in this process has increased our understanding in recent years and led to improved
mapping of relationships
LO5

RNA Modifications in Gene Regulation
More than 100 chemical modifications can
take place on both coding and noncoding
RNA
Affect stability, structure, localization,
translation, and splicing
Previous example: RNA Editing via Base
Deamination
New Example: Pseudouridylation of RNA
◦ Chemically modifies uridine into
pseudouridine via isomerization
◦ Role in stabilizing RNA conformations and
destabilizing RNA-protein interactions
◦ Example: tRNA stability and activity for aminoacyl-tRNA
synthetases
LO1, LO2,
LO3

Additional considerations for Gene Regulation
Some changes in DNA methylation, histone modification, non-coding RNA biogenesis, and
chromatin remodeling can be inherited into the next generation
◦ These play crucial roles in genomic functions and regulation of gene expression

The human inactivated X chromosome (Xi) and the Y chromosome have the ability to regulate
and modulate the expression of thousands of autosomal and active X genes
◦ While the overall effects of the two chromosomes appear to be similar, transcriptomic differences exist
for this regulation particularly in cells outside the reproductive tract
◦ More research is needed to understand the full implications for gene regulation by Xi and Y
chromosomes
◦ Epigenetic differences across males and females as well as across cell types are likely playing a role in
this
LO1, LO2,
LO3, LO6

Heritable Gene Expression Profiles
The variation of gene expression correlated with differentiation in a
multicellular organism is just one level of understanding for heritable gene
expression profiles
Even within cell populations that are expected to be clonally identical it is
possible to find heritable patterns of gene expression and functional
heterogeneity that can be maintained
◦ Clonal Identities
This is an important implication for cancer genetics
◦ Identified heterogeneous tumors may in fact have a greater degree of functional
heterogeneity
◦ Previously believed clonal tumors may in fact have a wide range of functional
heterogeneity in the form of multiple clonal identities
◦ Significant implications for consequences of therapeutic interventions and in vitro cancer studies
LO1

Revisiting Prokaryotic Friends
A quick summary with a few questions…
INDUCIBLE REPRESSIBLE
Usually encode catabolic enzymes Usually encode anabolic enzymes
Why does this make sense? Why does this make sense?
◦ Only want to synthesize the molecules of ◦ Want to synthesize the molecules of building
breakdown when the thing you want to break unless you already have all the building
down is present materials you need
LO1, LO7,
LO8

Operon Model
The operon consists of several structural
genes required for metabolism under the
control of a single regulatory domain
= coordinate regulation
Repressor binding site = operator
◦ A gene may have multiple operators upstream
and/or between structural genes controlled by
the same promoter
Site for transcriptional activation = promoter
An operon is induced when RNA polymerase
is free to associate and initiate transcription
LO7, LO8

Lac Operon Quick Summary
Regulates lactose degradation
◦ Lactose permease and β-galactosidase
Off (as much as possible) until wanted ON
Can be both activated and repressed
◦ Absence of lactose suppresses operon though
low levels of activity are still expected
◦ Binding of Lac I (repressor) to operator turns
OFF; must inactivate repressor to turn ON
◦ Presence of GLUCOSE shuts OFF operon
because GLUCOSE is a preferred fuel
◦ When lots of glucose metabolism = low cAMP and lac
operon is OFF (even in absence of repressor)
◦ When glucose metabolism is absent = high cAMP and lac
operon can be ON (unless repressor is present)
◦ Presence of lactose induces lac operon activity
including promoting proteins that increase
lactose uptake into cell
Brooker et al McGraw Hill 2021
LO1, LO7,
LO8

Trp Operon Quick Summary
Makes the enzymes necessary to synthesize
tryptophan
ON until you have made enough
Regulation via both negative feedback and
attenuation (folding that prevents activity of
the polymerase and/or ribosome; see next
slides)
Presence of tryptophan generates
APOREPRESSOR complex that suppresses
transcription
Charged tRNA with trp (trp-tRNA/tRNA-trp)
can act as a repressor of both transcription
and translation (see next slides)
LO7, LO8,
LO9
Additional Regulation of the trp Operon:
Attenuation
Attenuation results in the premature termination of mRNA or protein synthesis
due to stem and loop formation in the 5’ region of mRNA
◦ trp attenuator sequence
◦ complementary bases pair to form a stem and loop structure

Brooker et al McGraw Hill 2021
 LO7, LO8, LO9

Regulation of trp via tRNA
Availability of charged tRNA molecules can alter both
transcription and translation
tRNA-trp is present = OFF
◦ Synthesis of the leader peptide results in pairing of mRNA in a
manner that blocks the action of the ribosome

Low or absent trp-tRNA = ON
◦ mRNA takes on different conformation and ribosome can
function to continue synthesis

Also affects TRANSCRIPTION and activity of RNA
Polymerase or RNA pol association with operon

Merino et al 2008
LO9

Additional Translational
Regulation
Any binding or folding that impacts
ribosome association with the
mRNA will impact translation
Antisense RNA can inhibit
translation
◦ Hybridizes with mRNA forming double-
stranded molecule that prevents
ribosome association
LO9, LO10

Regulation of Translation in Eukaryotes
Regulation is not only in terms of the timing of translation but
also in the location of translation
Important in development particularly in terms of spatial
patterning of structures
Dysregulation of translation is linked to human disease
Areas of import include:
◦ tRNA dysfunction
◦ Ribosomopathies
◦ Stress responses
◦ mTOR pathway
Translational rates and functional activity can help explain the
tissue-specificity of human diseases
LO9, LO10
mRNA Transcript Regulation and Translational
Regulation
Regulation by RNA-binding proteins
associating with noncoding elements
Can influence translation or alter mRNA
degradation
Example: Iron assimilation genes
◦ Iron regulatory proteins (IRP) and Iron response
elements (IRE)
◦ Low concentrations of Iron free IRP to bind IRE and
suppress translation (B of image)
◦ High concentrations of Iron bind IRP keeping IRE
open and allowing translation to proceed (E of
image)

Zhou and Tan 2017
LO9, LO10

CAP-Independent Regulation of
Translation
Canonical cap-dependent initiation of translation involves the
traditional assembly and scanning methodology outlined
previously
Under stress conditions or physiological challenges, a cap-
independent initiation method exists
Internal Ribosome Entry Site (IRES) elements
◦ Related to selective cellular protein synthesis
◦ Mostly located in genes associated with stress, mitosis, or
apoptosis
◦ Located in 5’ UTRs and can interact with key binding factors (ITAF)
to remodel and encourage ribosome recruitment
First discovered in poliovirus, these elements have sequence uORF = upstream open reading
or structural motifs that recruit translation machinery and,
thus, can initiate translation frames
LO11

Consequences of Change
Changes in the sequence of regulatory elements (particularly where sequence specific-binding
occurs) can have significant impacts on regulation outcomes
Loss of function has different outcomes depending on the activity or role:
◦ Lack of binding at the operator = no repression
◦ Lack of binding at the promoter = no activity/transcription
◦ Lack of lactose availability = little to no activity (minimal activity) of the lac operon
◦ Iron required for activity and iron present = translation occurs
◦ Iron blocks activity and iron present = translation is blocked

Gain of function has different outcomes as well!
Questions for your consideration…
Which operon example is turned on when needed? (LO4, LO5)
Which operon example also has significant translational regulation? (LO4, LO5)
Translational regulation in eukaryotes can be thought of as a method that affects the level of translation and/or
_________? (LO6)
What is the role of mRNA higher order structures in regulation? (LO6)
High levels of glucose are available in the environment along with high levels of lactose. What is the most likely
consequence for the lac operon in terms of relative activity? (LO4, LO5, LO7)
MORE LO7:
What is the expected consequence in terms of gene expression for the following changes:
constitutive binding of repressor to operator?
constitutive binding of cAMP to operon?
A change in sequence prevents mRNA folding. If folding was necessary to enable full transcription of the mRNA, what is
the consequence in terms of functional product?