Lecture 14 (PT Reg Bacterial Gen Exp, ch 20) PDF

Summary

This document is a lecture on post-transcriptional regulation of gene expression in bacteria. It covers key topics, including riboswitches and the regulation of gene expression. It presents examples of riboswitches, including those for Vitamin B2 and related concepts.

Full Transcript

BIOL 366 Lecture 14
Post transcriptional regulation of gene expression

Readings:

Text Section: 20.2.1 – 20.2.2 and

Articles (on library reserve):
1. Antibiotic Resistance: Current Perspectives. Authors: Anushya Petchiappan and
Dipankar Chatterji. Source: ACS Omega 2017, 2, 7400-7409.
2. The ribB FMN riboswitch from Escherichia coli operates at the transcriptional and
translational level and regulates riboflavin biosynthesis. Authors: Danielle
Pedrolli1, Simone Langer, Birgit Hob, Julia Schwarz, Masayuki Hashimoto and
Matthias Mack. Source: FEBS Journal 282 (2015) 3230–3242.
doi:10.1111/febs.13226

Key terms: riboswitch, translational repressor, stringent response, stringent factor.

Text (Chapter 20) problems: 10, 11, 13, 14, 15, 17, 18.

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Review of Last lecture:
Transcriptional control of gene expression in bacteria:
▪ lac operon; positive and negative regulation with different proteins
▪ ara operon: positive and negative regulation with same proteins
▪ trp operon: Attenuation

Next, we look at posttranscriptional control of control of gene
expression for the “rapid up- or down-regulation of protein synthesis
in response to molecular signals”

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 Regulation via translational feedback:
Example: The r-protein operons
In bacteria, increased demand for protein synthesis is met by
increasing the number of ribosomes.

– Ribosomal proteins can make up to 45% of total cellular proteins in rapidly
growing cells

Bacteria coordinate the synthesis
of the ribosomal components

r-proteins

r-RNAs

FIGURE 18-3 3
 Regulation via translational feedback: The r-protein operons

The r-proteins are encoded by 52 genes, present in ~20 operons (1-11 genes, each)

One r-protein in each operon functions as a translational repressor

– The repressor can bind rRNA (preferred)
– The repressor can also bind the operon’s mRNA and blocks its translation

Fig 20-18: One r-protein operon 4
Regulation of an r-protein operon via translational feedback mechanism
When [r-protein] is low relative to [rRNA]:
The translational repressor (L4) bind rRNA only

L4 is NOT available to bind r-protein mRNA

Translation proceeds

Fig 20-18

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Regulation of an r-protein operon via translational feedback mechanism

When [r-protein] is higher than [rRNA] (no need for more r-protein)

L4 proteins saturate rRNA

Some L4 protein bind mRNA and repress translation

Fig 20-18

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Some RNA species have regulatory
elements/regions known as Riboswitches.

Riboswitches:

Exist within the 5′ untranslated
region (5′UTR) of mRNA

Are found in bacteria and some
eukaryotes (typically not mammals)

Are most common in bacteria.

Include:
a regulatory region
a [small molecule / metabolite]–binding element

Fig. 20-14
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Riboswitches can function at the level of transcription

Transcription proceeds when
mRNA is not bound to metabolite

Specific metabolite binds the
molecule–binding element

Binding of metabolite (the
ligand) changes the shape of the
entire RNA molecule

Transcription is terminated

Fig. 20-14

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Riboswitches can function at the level of translation

No specific metabolite:

Translation proceeds

Specific metabolite present:

Metabolite binds and alter
mRNA structure

Sequesters the Shine-
Dalgarno sequence

Halts translation

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Example: The thiamine pyrophosphate (TPP)–binding riboswitch AKA THI box
or THI element (Note: TPP is the active form of thiamine AKA vitamin B1)

The THI box / element:

Is located in the 5′UTR region of mRNAs involved
in vitamin B1 biosynthesis

Controls gene expression by inhibiting translation
when [vitamin B1] is high

Is one of the few riboswitches found across most
organisms (archaea, some eukaryotes, and bacteria)

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Mode of action of the TPP riboswitch

When TPP is present (upper diagram)

– TPP binds the riboswitch

– The riboswitch changes conformation

– The Shine-Dalgarno sequence is
sequestered

– Translation is prevented

When TPP is NOT present (lower diagram)

– Translation is on

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Riboswitches can affect mRNA stability; e.g., the glmS riboswitch.

Note: The glmS gene encodes an enzyme that catalyzes the reaction:

Fructose 6-phosphate + glutamine → glucosamine 6-phosphate

Glucosamine 6-phosphate (GlcN6-P) controls
the expression of the glmS mRNA

On binding of GlcN6-P, the glmS pre-mRNA
degrades itself (i.e., it is a ribozyme), so more
enzyme is NOT produced,

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 Riboswitches can discriminate between chemically related molecules

Discrimination can be based on:

Atomic charge

Stereochemistry

The presence or absence of
particular functional groups

Example: The glmS riboswitch.

Fig. 20-17: Structure of (GlcN6-P),
the metabolite for the glmS
riboswitch, and a few of its analogs.

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Riboswitches can be very specific to their ligands.

Result of agarose gel electrophoresis of ribonuclease-cleaved samples (Fig. 20-17c).

The glmS mRNA was incubated with its known effector (glucosamine 6-phosphate)
or the other compounds shown in (b).

The riboswitch specifically recognizes GlnN6P

Fig. 20-17c: Degradation of glmS mRNA triggered by different ligands. 14
 Some properties of riboswitch-regulated mRNAs

(1) Have unusually long sequences upstream from the translation start site that
are necessary to form the riboswitch.

(2) The upstream sequence is well-conserved in the same mRNA in different
bacterial species, and sometimes in archaea, plants, and fungi.

(3) Do not have protein binding partners, consistent with their ability to function
directly to regulate gene expression.

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 There are several classes of Riboswitches (RS)
RS’s are named after the ligand they bind

Over 15 classes are known, classified based on ligand type and RS secondary structure.

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 Utility of riboswitches in
controlling bacterial growth

Many bacteria are developing resistance to
antibiotics. How?

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 Overview of metabolic pathways
targets for some common antibiotics

Reference: Antibiotic Resistance: Current Perspectives, by Anushya Petchiappan and 18
Dipankar Chatterji. ACS Omega 2017, 2, 7400-7409.
Major mechanisms of antibiotic resistance development.

Figure 2a. Resistant bacteria can:

- Decrease antibiotic influx

- Increase antibiotic efflux 19
Major mechanisms of antibiotic resistance development.

Figure 2b. Resistant bacteria
– Degrade antibiotic

– Modify antibiotic by adding
chemical group
20
 Major mechanisms of antibiotic resistance development.

Figure 2c. Resistant bacteria

- Protect antibiotic target

- Produce alternative protein to do the function
Figure 2. Three main mechanisms of antibiotic resistance development in bacteria. 21
 Utility of Riboswitches; the FMN (Flavin mononucleotide) riboswitch

Example: The FMN riboswitch.
– This riboswitch controls the expression of genes involved in the biosynthesis of riboflavin (vitamin B2)
– Riboflavin is a precursor to synthesizing cofactors like FMN
– The pathway is essential in the Mycobacterium tuberculosis, as it lacks riboflavin transport genes

Structures of FMN,
roseoflavin antibiotic,
and ribocil-C.

Note: Roseoflavin and Ribocil-C inhibit synthesis of vitamin B2 and FMN

Reference: Antibiotic Resistance: Current Perspectives, by Anushya Petchiappan and Dipankar
22
Chatterji. ACS Omega 2017, 2, 7400-7409.
Background on riboflavin (vitamin B2) biosynthesis:
In eubacteria (e.g., E. coli & B. subtilis) riboflavin (vitamin B2) is synthesized from
GTP and two molecules of ribulose 5-phosphate via a series of enzymatic reactions.

The enzymes involved are:

i) GTP cyclohydrolase II (RibA)
ii) 3,4-dihydroxy2-butanone-4-phosphate synthase (RibB)
iii) a riboflavin-specific deaminase/reductase (RibDG)
iv) lumazine synthase (RibH)
v) Riboflavin synthase (RibE)
vi) RibCF

These genes are part of a single transcription unit (ribDG-E-AB-H) whose
expression is regulated by a FMN riboswitch (ribDG FMN riboswitch) located in
the 50 -UTR of the “ribDG-E-AB-H” mRNA. 23
 Utility of Riboswitches; the FMN riboswitch
In the absence of FMN, mRNAs for
enzymes of riboflavin synthesis are
produced and translated.

Binding of FMN to its target results
in a conformational change and
formation of a terminator/sequester
loop, thereby abolishing gene
expression.

Both transcription & translation can
be inhibited with this riboswitch.

Note: Roseoflavin and Ribocil-C
bind FMN riboswitch and inhibit
synthesis of vitamin B2 and FMN

Reference: Antibiotic Resistance: Current Perspectives, by Anushya Petchiappan 24
and Dipankar Chatterji. ACS Omega 2017, 2, 7400-7409.
Utility of Riboswitches; the FMN (Flavin mononucleotide) riboswitch

Structures of FMN,
roseoflavin antibiotic,
and ribocil-C.

Note: Roseoflavin and Ribocil-C mimic FMN inhibit synthesis of vitamin B2 and FMN

Reference: Antibiotic Resistance: Current Perspectives, by Anushya Petchiappan and Dipankar
25
Chatterji. ACS Omega 2017, 2, 7400-7409.