Module 3 Molecular Biology PDF

Summary

This document contains lecture notes on module 3 of molecular biology, focusing on transcription and post-transcriptional modifications in prokaryotes and eukaryotes. It includes definitions and explanations related to genes, genomes, operons, and other important concepts.

Full Transcript

MIT School of Bioengineering Sciences and Research
(A Constituent unit of MIT ADT University)

Module: 3

Module Name: Transcription and post
transcriptional modifications

Course Code: 21BBT301 Course Coordinator:
Course Name: Molecular Biology Contact Number:
Module: 3 Mail ID:
Disclaimer:

The content delivered here should be considered of utmost importance. However, it is
to be noted that, this material is not Stand-alone material for the fulfilment of the
course syllabus. The content in this presentation should only be used as an aid to
learning.
Books and other resources provided are suggested to be referred for exhaustive
understanding.

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Objective/Learning Outcome:

Understand the principles behind the central dogma of
molecular biology: DNA replication, transcription, and
translation.
Enable to learn the regulation of gene expression in
prokaryotes and Eukaryotes.

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Syllabus:

Fine structure of prokaryotic and eukaryotic gene, structure and
function of the promoters in mRNA, rRNA, tRNA genes.
RNA polymerases in prokaryote and eukaryote, types and function.
Transcription of mRNA, rRNA, and tRNA genes in Prokaryotes and
Eukaryotes.
Post transcriptional processing of mRNA – 5’capping, splicing,
polyadenylation and RNA editing.

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 Gene
○ Part of DNA, where the particular DNA sequence determines the function.
Genome
○ the haploid set of chromosomes in a gamete or microorganism, or in each cell of a multicellular
organism.
○ the complete set of genes or genetic material present in a cell or organism.
Open reading frames (ORFs)
○ spans of DNA sequence between the start and stop codons
Operon
○ A functioning unit of DNA containing a cluster of genes under the control of a single promoter
Riboswitch
○ In molecular biology, a riboswitch is a regulatory segment of a messenger RNA molecule that
binds a small molecule, resulting in a change in production of the proteins encoded by the
mRNA
transcription factor (TF)
○ In molecular biology, a transcription factor (TF) (or sequence-specific DNA-binding factor) is a
protein that controls the rate of transcription of genetic information from DNA to messenger
RNA, by binding to a specific DNA sequence

Source WikiJournal of Medicine, 2017, 4(1):2 Figure Article, available at: https://doi.org/10.15347/wjm/2017.002

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 enhancer
○ A short (50–1500 bp) region of DNA that can be bound by proteins (activators) to
increase the likelihood that transcription of a particular gene will occur
Repressor
○ DNA- or RNA-binding protein that inhibits the expression of one or more genes by
binding to the operator or associated silencers.
A transcriptional activator
○ Protein (transcription factor) that increases transcription of a gene or set of genes
silencer
○ In genetics, a silencer is a DNA sequence capable of binding transcription
regulation factors, called repressors.
Promoter
○ a sequence of DNA to which proteins bind to initiate transcription of a single RNA
transcript from the DNA downstream of the promoter.
A regulatory sequence
○ a segment of a nucleic acid molecule which is capable of increasing or decreasing
the expression of specific genes within an organism.
Source WikiJournal of Medicine, 2017, 4(1):2 Figure Article, available at: https://doi.org/10.15347/wjm/2017.002

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 Features of prokaryotic genome
○ Most prokaryotic cells are small and most genes are expressed at relatively low
levels. Cell doubles in 20 min (fast). DNA interacts directly with molecular
machines in the cytoplasm.
○ size of prokaryotic genomes ranges from around 50 kb to more than 13 Mb
○ genomes are also very compact, with gene density typically approaching 85%
Shortcomings of prokaryotic genome
○ smaller genomes are nearly depleted of sensory, transport, communication, and
regulatory functions, reflecting narrow environmental ranges
○ Natural selection is more efficient in larger genomes, possibly as a result of
larger effective population sizes.
○ Larger genomes correspond to more versatile prokaryotes that are less sexually
isolated and in which selection is more efficient.
Source: Touchon M, Rocha EP. Coevolution of the Organization and Structure of Prokaryotic Genomes. Cold Spring Harb Perspect Biol. 2016 Jan
4;8(1):a018168. doi: 10.1101/cshperspect.a018168. PMID: 26729648; PMCID: PMC4691797.

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 Fine structure of prokaryotic genome
○ lack a clear physical separation between DNA and the cytoplasm. cell doubles in 20
min. DNA interacts directly with molecular machines in the cytoplasm.
○ high rates of horizontal gene transfer and gene loss.
○ Genome replication, segregation, and cell doubling are tightly linked
○ Transcription, translation, and protein localization are tightly linked & nascent
transcripts are immediately translated by multiple ribosomes.
○ cells endure intense gene expression and collisions between the rapid replication
fork and the relatively slower RNA polymerases are frequent.
○ SOS or SOS-like responses may kick off the transfer of mobile genetic elements to
other cells

Source: Touchon M, Rocha EP. Coevolution of the Organization and Structure of Prokaryotic Genomes. Cold Spring Harb Perspect Biol. 2016 Jan
4;8(1):a018168. doi: 10.1101/cshperspect.a018168. PMID: 26729648; PMCID: PMC4691797.

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 Traits associated with polyploidy in
prokaryotes. The presence of multiple
copies of replicons, and particularly
chromosomes, has been proposed to
confer several advantages. (A) It allows
distributing gene expression through the
entire cytoplasm in very large cells. It
allows heterozygosity. In the presence of
several replicons, the ratio between
replicons allows gene expression
regulation. (B) It allows repair by
homologous recombination with other
similar replicons. (C) Recombination
between similar replicons also allows
gene conversion and allelic exchange.
Heterozygosity is indicated using distinct
colors (red and black).
Source: Touchon M, Rocha EP. Coevolution of the Organization and
Structure of Prokaryotic Genomes. Cold Spring Harb Perspect Biol.
2016 Jan 4;8(1):a018168. doi: 10.1101/cshperspect.a018168. PMID:
26729648; PMCID: PMC4691797.

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 Organization of prokaryotic genome
○ Prokaryotes endure high rates of rearrangement, mutation, deletion, and accretion
of genetic material.
○ Genomes are polyploid, with certain species carrying more than 100 copies of the
chromosome per cell, allowing distributing gene expression through the entire
cytoplasm in very large cells. (heterozygosity).
○ In the presence of several replicons, the ratio between replicons allows gene
expression regulation.Facilitates repair and homologous recombination
○ In newly replicated cells, the macrodomains around the origin (Ori) and terminus
(Ter) of replication are localized near opposite cell poles leading to a linear
arrangement of the genetic information in the cell
○ Thus, completely symmetric, with origin and terminus separated by ∼180° in circular
replicons, so that both forks complete replication synchronously. multiple replication
forks are common in fast growing bacteria
Source: Touchon M, Rocha EP. Coevolution of the Organization and Structure of Prokaryotic Genomes. Cold Spring Harb Perspect Biol. 2016 Jan
4;8(1):a018168. doi: 10.1101/cshperspect.a018168. PMID: 26729648; PMCID: PMC4691797.

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 Elements of Prokaryotic genome organization

Source: Touchon M, Rocha EP. Coevolution of the Organization and Structure of Prokaryotic Genomes. Cold Spring Harb Perspect Biol. 2016 Jan 4;8(1):a018168. doi: 10.1101/cshperspect.a018168. PMID: 26729648; PMCID: PMC4691797.

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 Operons in prokaryotic genome
○ The majority of genes in prokaryotes are expressed under the form of
polycistronic units called operons (may contain 2-12; average ∼3–4 genes:
often encode physically interacting proteins, often encode enzymes of
consecutive steps in metabolic pathways)
○ Organization of genes in operons is a compact way of regulating gene
expression because genes in the same operon are expressed at more similar
rates than random pairs of genes
○ SAFER: Pairs of contiguous genes in operons are highly conserved showing
rearrangement rates orders of magnitude lower than other interoperonic pairs
○ Large genomes have more complex genetic networks and many more different
transcription factors than small genomes. Thus, there is increased selection for
operons in small genomes.

Source: Touchon M, Rocha EP. Coevolution of the Organization and Structure of Prokaryotic Genomes. Cold Spring Harb Perspect Biol. 2016 Jan
4;8(1):a018168. doi: 10.1101/cshperspect.a018168. PMID: 26729648; PMCID: PMC4691797.

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 The genetic organization of gene expression

Schematic representation of
the transcription factory model,
in which multiple active RNA
polymerases are concentrated
at discrete sites in the nucleoid

Source: Touchon M, Rocha EP. Coevolution of the Organization and Structure of Prokaryotic
Genomes. Cold Spring Harb Perspect Biol. 2016 Jan 4;8(1):a018168. doi:
10.1101/cshperspect.a018168. PMID: 26729648; PMCID: PMC4691797.

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 The genetic organization of prokaryotic gene expression

(B) Bacterial genes are organized
into operons, which group in
superoperons. In addition to being
physically close in the genome,
genes in operons are
cotranscribed, coregulated, and
encode proteins involved in the
same functional pathway or
protein complex. Superoperons
are not cotranscribed, but may
share regulatory regions.

Source: Touchon M, Rocha EP. Coevolution of the Organization and Structure of
Prokaryotic Genomes. Cold Spring Harb Perspect Biol. 2016 Jan 4;8(1):a018168.
doi: 10.1101/cshperspect.a018168. PMID: 26729648; PMCID: PMC4691797.

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 The genetic organization of
prokaryotic gene expression

(C) Schematic
representation of three
models aiming at
explaining the formation
and conservation of
operons based on genetic
linkage.

Source: Touchon M, Rocha EP. Coevolution of the Organization and Structure of Prokaryotic
Genomes. Cold Spring Harb Perspect Biol. 2016 Jan 4;8(1):a018168. doi:
10.1101/cshperspect.a018168. PMID: 26729648; PMCID: PMC4691797.

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 The genetic organization of prokaryotic gene expression
(D) Transcription of genes in a
single transcript is expected to
diminish gene expression noise
and ensure more precise
stoichiometry. It also allows
responding optimally to demand for
a given pathway when the first
genes to be transcribed are those
starting the functional pathway.

(E) Operons place several genes
under the same regulatory region
that is thus subject to more efficient
selection.
Source: Touchon M, Rocha EP. Coevolution of the Organization and Structure of
Prokaryotic Genomes. Cold Spring Harb Perspect Biol. 2016 Jan 4;8(1):a018168.
doi: 10.1101/cshperspect.a018168. PMID: 26729648; PMCID: PMC4691797.

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 Prokaryotic Gene structure
○ ORFs are often grouped into a polycistronic operon under the control of a shared set
of regulatory sequences.These ORFs are all transcribed onto the same mRNA and so
are co-regulated and often serve related functions.
○ Each ORF typically has its own ribosome binding site (RBS) so that ribosomes
simultaneously translate ORFs on the same mRNA
○ Having multiple ORFs on a single mRNA is only possible in prokaryotes because their
transcription and translation take place at the same time and in the same subcellular
location.
○ The operator sequence next to the promoter is the main regulatory element in
prokaryotes. Repressor proteins bound to the operator sequence physically
obstructs the RNA polymerase enzyme, preventing transcription
○ Riboswitches switch between alternative secondary structures in the RNA depending
on the concentration of key metabolites. The secondary structures then either block or
reveal important sequence regions such as RBSs.
○ Introns are extremely rare in prokaryotes and therefore do not play a significant role
in prokaryotic gene regulation.

Source: WikiJournal of Medicine, 2017, 4(1), Figure Article. Available at: https://doi.org/10.15347/wjm/2017.002
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 The structure of a prokaryotic operon of protein-coding genes. Regulatory sequence controls when expression occurs for the multiple protein
coding regions (red). Promoter, operator and enhancer regions (yellow) regulate the transcription of the gene into an mRNA. The mRNA
untranslated regions (blue) regulate translation into the final protein products
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 Eukaryotic Gene structure
○ ORFs are often grouped into a polycistronic operon under the control of a shared set of
regulatory sequences.These ORFs are all transcribed onto the same mRNA and so are
co-regulated and often serve related functions.
○ Each ORF typically has its own ribosome binding site (RBS) so that ribosomes
simultaneously translate ORFs on the same mRNA
○ Having multiple ORFs on a single mRNA is only possible in prokaryotes because their
transcription and translation take place at the same time and in the same subcellular
location.
○ The operator sequence next to the promoter is the main regulatory element in prokaryotes.
Repressor proteins bound to the operator sequence physically obstructs the RNA
polymerase enzyme, preventing transcription
○ Riboswitches switch between alternative secondary structures in the RNA depending on
the concentration of key metabolites. The secondary structures then either block or reveal
important sequence regions such as RBSs.
○ Introns are extremely rare in prokaryotes and therefore do not play a significant role in
prokaryotic gene regulation.
Source: WikiJournal of Medicine, 2017, 4(1), Figure Article. Available at: https://doi.org/10.15347/wjm/2017.002
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 Prokaryotic Transcription
RNA polymerase is an enzyme that transcribes DNA into RNA in
prokaryotic cells. Prokaryotic cells have a single RNA polymerase
that transcribes all three major classes of RNA. RNA polymerase
synthesizes RNA by following a strand of DNA.

Types:
○ RNA polymerase I: Transcribes rRNA
○ RNA polymerase II: Transcribes mRNA
○ RNA polymerase III: Transcribes tRNA, 5S RNA, and other
small RNAs

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 Subunits of RNA polymerase
1. α (Alpha): involved in enzyme assembly and also binds to specific
DNA sequences.
2. β (Beta): forms the catalytic center, elongating the growing RNA
chain.
3. β’ (Beta Prime): Together with β, it ensures accurate initiation and
elongation.
4. σ (Sigma): confers precision by binding to promoter regions,
marking the spot where transcription begins.
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 Why greek letters are used in polymerase subunits?

Greek letters are used to designate the subunits of RNA
polymerase to provide a clear and systematic way to identify and
differentiate them.
Each subunit has a specific function and structure, and using
Greek letters helps in categorizing these roles efficiently.

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 Why greek letters are used in polymerase subunits?
Historical Background
○ Early Discoveries
The discovery of RNA polymerase and its subunits dates back to the
mid-20th century.
As scientists began to identify and characterize the different components
of RNA polymerase, they needed a systematic way to name these
subunits.
○ Greek Alphabet
A simple and clear way to differentiate between multiple subunits within
the same enzyme complex.
This method was already in use in other areas of science, making it a
familiar and convenient choice.
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 Why greek letters are used in polymerase subunits?
Historical Background
○ Early Discoveries
The discovery of RNA polymerase and its subunits dates back to the
mid-20th century.
As scientists began to identify and characterize the different components
of RNA polymerase, they needed a systematic way to name these
subunits.
○ Greek Alphabet
A simple and clear way to differentiate between multiple subunits within
the same enzyme complex.
This method was already in use in other areas of science, making it a
familiar and convenient choice.
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 The DNA sequence (grey), The −35
and −10 (Pribnow box) elements are
shaded yellow, the extended −10 &
discriminator elements (purple)
Subunits (αI, αII, ω, grey; β, light cyan;
β′, light pink; Δ1.1σA, light orange)
Active site Mg2+ (yellow sphere) and
the nucleic acids held inside the RNAP
active site channel.

Brian Bae, Andrey Feklistov, Agnieszka Lass-Napiorkowska, Robert Landick, Seth A Darst (2015) Structure of a bacterial RNA
polymerase holoenzyme open promoter complex eLife4:e08504. https://doi.org/10.7554/eLife.08504
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 Prokaryotic Transcription
Bacteria have the simplest form of RNA polymerase made up of several proteins
that work together to make RNA using DNA as a template
RNA polymerase and the sigma factor interact the resulting group of proteins is
known as the RNA polymerase ‘holoenzyme’
Transcription initiation is a major control point of gene expression.
A conserved ∼400 kD catalytic core of the RNA polymerase (RNAP or E, subunit
composition α2ββ′ω)
○ combines with the promoter-specificity factor σA to form the holoenzyme (EσA),
○ which locates promoter DNA and unwinds 12–14 base pairs (bps) of the DNA duplex
○ to yield the transcription-competent open promoter complex (RPo)
In the presence of nucleotide substrates, RNA synthesis begins with the formation
of an initial transcription complex (RPITC), transitioning to a stable elongation
complex
Eventually, the transcript reaches a length of around 17 nt, where σ dissociation
and the transition to the stable elongation complex begins
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 Transcription elongation
The elongation cycle comprises three basic steps:

1. Binding of a template-complementary nucleoside triphosphate
(NTP) into the active site;

2. Chemical reaction of the RNA chain 3′-OH with the NTP α-PO4,
catalyzed by a pair of bound Mg2+ ions, resulting in one NMP
addition to the RNA and liberation of pyrophosphate; and

3. Translocation of the nucleic acid assemblage to place the next
template base in the active center
 Transcription elongation
The elongation complex of RNAP (Figure 1) is stabilized by several sets of
interactions such as:

1. downstream duplex DNA is bound within the enzyme;
2. about nine nucleotides of RNA at the growing end are annealed to
the template DNA strand, forming a 9-bp RNA/DNA hybrid
enclosed by protein; and
3. an additional ~5 nucleotides of RNA upstream of the hybrid are
bound in a protein channel until the RNA emerges 14 nucleotides
from the growing end
 Transcription elongation
Transcription elongation in prokaryotes is the
phase of mRNA synthesis that occurs
after the σ subunit dissociates from the
polymerase, allowing the core enzyme to
move along the DNA template.
The core enzyme then synthesizes mRNA in
the 5' to 3' direction Rate = 40 nt per sec.
As it moves, the polymerase unwinds the
DNA template ahead of it and rewinds it
behind it, keeping an open region of about
17 base pairs for transcription

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 Transcription elongation
1. DNA is continuously unwound ahead of the core enzyme and rewound behind it.
2. Base pairing between DNA and RNA is not stable hence , RNA polymerase acts as a
stable linker between the DNA template and the nascent RNA strands to ensure that
elongation is not interrupted.
3. Elongation is NOT uniform and inevitable, but modulated by regulatory influences to
fast/slow/stop
a. anti terminators,
b. operon-specific genetic regulatory elements
c. RNA can be a regulatory element. Thus, in regulation by an attenuator RNA or
riboswitches
d. Blocked by accident: a non coding lesion (a thymine dimer) is in the DNA template
or clashes in replication and recombination. Here transcription complex is
removed.
Roberts, J. W., Shankar, S., & Filter, J. J. (2008). RNA polymerase elongation factors. Annual review of microbiology, 62, 211–233. https://doi.org/10.1146/annurev.micro.61.080706.093422

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 Transcription elongation

Polymerase is accurate (?) - only about 1 error in 10,000 bases (error rate
is OK, since many transcripts are made from each gene)
Elongation rate is 20-50 bases per second - slower in G/C-rich regions
(why??) and faster elsewhere
Topoisomerases precede and follow polymerase to relieve supercoiling
 Termination of prokaryotic transcription
Transcription can terminate in two ways: rho-dependent or
rho-independent.
○ Rho-dependent termination occurs when the rho protein
collides with the polymerase at a stretch of G nucleotides
near the end of the gene.
○ Rho-independent termination occurs when the
polymerase stalls at a stable hairpin formed by
complementary C–G nucleotides at the end of the mRNA

Roberts, J. W., Shankar, S., & Filter, J. J. (2008). RNA polymerase elongation factors. Annual review of microbiology, 62, 211–233. https://doi.org/10.1146/annurev.micro.61.080706.093422

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Eukaryotic transcription
Prokaryotes and eukaryotes both perform transcription similarly, but with key
differences. Eukaryotic mRNA synthesis is much more complex than in
prokaryotes.
Eukaryotes have a membrane-bound nucleus and organelles. Eukaryotic
cells must transport mRNA to the cytoplasm and protect it from
degradation before translation.
Eukaryotes have three polymerases, each with over 10 subunits, compared
to the single five-subunit polymerase in prokaryotes.

Additionally, each eukaryotic polymerase needs a unique set of transcription
factors to bind to the DNA template. Their mRNAs are typically monogenic,
specifying a single protein.
 Eukaryotic transcription
RNA polymerase I is found in the nucleolus, where it transcribes rRNA, except
for 5S rRNA. These rRNAs are structural and essential for translation.
RNA polymerase II, located in the nucleus, synthesizes protein-coding
pre-mRNAs, which undergo extensive processing before translation.
RNA polymerase III, also in the nucleus, transcribes 5S pre-rRNA, pre-tRNAs,
and small nuclear pre-RNAs. These small RNAs play roles in translation and
splicing.

The sensitivity of these polymerases to α-amanitin, a toxin from the Death Cap
mushroom, varies: RNA polymerase I is insensitive, RNA polymerase II is
highly sensitive, and RNA polymerase III is moderately sensitive. This
sensitivity helps researchers identify which polymerase transcribes a gene.
Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 Eukaryotic RNA Polymerases and General Transcription Factors

Cellular Product of α-Amanitin
RNA Pol
Compartment Transcription Sensitivity
All rRNAs except 5S
I Nucleolus Insensitive
rRNA
All protein-coding Extremely
II Nucleus
nuclear pre-mRNAs sensitive
5S rRNA, tRNAs, and small Moderately
III Nucleus
nuclear RNAs sensitive
Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
Type of RNA synthesized RNA polymerase

Nuclear genes

mRNA II

tRNA III
~Some small nuclear (sn) and small
rRNA cytoplasmic (sc) RNAs are transcribed by
polymerase II and others by polymerase III.
5.8S, 18S, 28S I

5S III *The mitochondrial and chloroplast RNA
polymerases are similar to bacterial
snRNA and scRNA II and III~ enzymes.

Mitochondrial genes Mitochondria

Chloroplast genes Chloroplast*
https://www.ncbi.nlm.nih.gov/books/NBK9935/
 Eukaryotic transcription
RNA polymerase I is found in the nucleolus, where it transcribes rRNA,
except for 5S rRNA. These rRNAs are structural and essential for
translation.
RNA polymerase II, located in the nucleus, synthesizes protein-coding
pre-mRNAs, which undergo extensive processing before translation.
RNA polymerase III, also in the nucleus, transcribes 5S pre-rRNA,
pre-tRNAs, and small nuclear pre-RNAs. These small RNAs play roles in
translation and splicing.
The sensitivity of these polymerases to α-amanitin, a toxin from the Death
Cap mushroom, varies: RNA polymerase I is insensitive, RNA
polymerase II is highly sensitive, and RNA polymerase III is moderately
sensitive. This sensitivity helps researchers identify which polymerase
transcribes a gene.
Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 Structure of an RNA Polymerase II Promoter

Eukaryotic promoters are larger and more complex than
prokaryotic ones, but both contain a TATA box.
In the mouse thymidine kinase gene, the TATA box is around
-30 from the initiation site and has the sequence TATAAAA.
This sequence, while different from the E. coli TATA box,
maintains the A-T rich element, aiding in DNA unwinding
for transcription.

Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 A generalized promoter of a gene transcribed by RNA polymerase II. Transcription
factors recognize the promoter. RNA pol II then binds and forms the transcription
initiation complex.

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 Transcription Factors for RNA Polymerase II
Eukaryotic transcription involves more than just polymerases and promoters.
Basal transcription factors, enhancers, and silencers regulate pre-mRNA synthesis.
Enhancers and silencers boost transcription efficiency but aren't essential. Basal
transcription factors, named TFII (A–J), form a preinitiation complex that recruits RNA
polymerase II.
RNA polymerases I and III use fewer transcription factors, but the process is similar.
Eukaryotic transcription is tightly regulated, requiring various proteins to interact with
DNA. This complex process ensures precise pre-mRNA synthesis for protein
production.

Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 Transcription Factors for RNA Polymerase II

Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 Transcription Factors for RNA Polymerase II

Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 Transcription Factors for RNA Polymerase II

Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 The Evolution of Promoters
Gene evolution through mutations during DNA replication can alter functions or
features, potentially benefiting the cell.
Similarly, eukaryotic promoters and regulatory sequences can evolve. If a gene
becomes more valuable, its promoter may evolve to recruit transcription factors
more efficiently, boosting gene expression.
Research on promoter evolution shows mixed results due to the difficulty in defining
promoter boundaries. Some promoters are within genes, others far upstream or
downstream.
However, studies on human core promoters show they evolve faster than
protein-coding genes. The impact of promoter evolution on higher organisms
remains unclear, but it offers an intriguing alternative to gene evolution.
Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 Promoter Structures for RNA Pol I and III
In eukaryotes, the conserved promoter elements differ for genes
transcribed by RNA polymerases I, II, and III.
RNA polymerase I transcribes genes that have two GC-rich promoter
sequences in the -45 to +20 region. Another promoter with additional
sequences in the region from -180 to -105 upstream of the initiation site
will further enhance initiation.
Genes that are transcribed by RNA polymerase III have upstream
promoters or promoters that occur within the genes themselves.

Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 Eukaryotic Transcription initiation
During initiation, RNA polymerase recognizes a promoter site upstream
of the gene and unwinds the DNA.
Most RNA polymerase II promoters have a TATA box around -25 from the
start site, aiding in positioning the enzyme for transcription. The TATA box
sequence is similar to the -10 sequence in prokaryotes and helps in
DNA unwinding.
Some genes lack a TATA box and use an initiator element instead. RNA
polymerase II requires general transcription factors (TFII) to form a
preinitiation complex. TFIID binds to the TATA box, followed by TFIIA,
TFIIB, RNA polymerase II (with TFIIF), TFIIE, and TFIIH, forming the
transcription initiation complex.
Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://microbenotes.com/eukaryotic-transcription/
 Eukaryotic Transcription initiation
During initiation, RNA polymerase recognizes a promoter site upstream
of the gene and unwinds the DNA.
Most RNA polymerase II promoters have a TATA box around -25 from the
start site, aiding in positioning the enzyme for transcription. The TATA box
sequence is similar to the -10 sequence in prokaryotes and helps in
DNA unwinding.
Some genes lack a TATA box and use an initiator element instead. RNA
polymerase II requires general transcription factors (TFII) to form a
preinitiation complex. TFIID binds to the TATA box, followed by TFIIA,
TFIIB, RNA polymerase II (with TFIIF), TFIIE, and TFIIH, forming the
transcription initiation complex.
Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://microbenotes.com/eukaryotic-transcription/
Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://microbenotes.com/eukaryotic-transcription/
 Eukaryotic Elongation
TFIIH has two main functions:

1. It acts as a helicase, using ATP to unwind the DNA helix for transcription to begin.

2. It phosphorylates RNA polymerase II, causing it to change shape and dissociate from
the initiation complex.

Phosphorylation occurs on the C-terminal domain (CTD) of RNA polymerase II.
Only non-phosphorylated RNA polymerase II can initiate transcription, while only
phosphorylated RNA polymerase II can elongate RNA.

RNA polymerase II then moves along the DNA, synthesizing RNA in the 5' to 3'
direction. The RNA produced from a protein-coding gene is called a primary
transcript.

Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 Eukaryotic Termination
Elongation continues until termination.

Unlike prokaryotic RNA polymerase, RNA polymerase II doesn't stop at a specific site
but can terminate at varying distances downstream of the gene.

It lacks specific termination signals and can transcribe RNA from a few to thousands
of base pairs past the gene's end.

The transcript is cleaved internally before RNA polymerase II finishes, releasing the
upstream portion as the initial RNA (pre-mRNA for protein-coding genes).

The remaining transcript is digested by a 5′-exonuclease (Xrn2 in humans).

When the exonuclease catches up to RNA polymerase II, it helps disengage the
polymerase, terminating transcription.

Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 RNA processing
The primary eukaryotic mRNA transcript, also known as hnRNA or pre-mRNA, is longer
and located in the nucleus. It undergoes steps to become mature RNA:

1. Cleavage: Larger RNA precursors are cleaved into smaller RNAs. The primary
transcript is cleaved by ribonuclease-P to form 5-7 tRNA precursors.

2. Capping and Tailing: A cap (7-methyl guanosine) is added to the 5′ end, and a poly-A
tail is added to the 3′ end. The cap is a modified guanosine triphosphate (GTP) molecule.

Eukaryotic primary mRNAs consist of non-coding introns and coding exons. Introns
are removed through RNA splicing, which uses ATP to cut the RNA, releasing introns
and joining exons to form mature mRNA.
1. Nucleotide Modifications: Common in tRNA, including methylation (e.g., methyl
cytosine), deamination (e.g., inosine from adenine), dihydrouracil, and pseudouracil.
Post-transcription processing is essential to convert the primary transcript into functional RNAs.
Sources:
1. Cooper GM. The Cell: A Molecular Approach. 2nd edition; 2000. Eukaryotic RNA Polymerases and General Transcription Factors. Available from: https://www.ncbi.nlm.nih.gov/books/NBK9935/
2. https://bio.libretexts.org/@go/page/1898?pdf
 Prokaryotic and Eukaryotic transcription

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 Prokaryotic and Eukaryotic transcription

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 Prokaryotic and Eukaryotic transcription

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 Prokaryotic and Eukaryotic transcription

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 Prokaryotic and Eukaryotic transcription

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 Prokaryotic and Eukaryotic transcription

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 Prokaryotic and Eukaryotic transcription

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 Prokaryotic and Eukaryotic transcription

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Post transcriptional Modifications
 5’ capping
7-methylguanosine (a modified nucleotide at the 5′ end) residues connected by a 5′-5′ triphosphate
bridge, is regulated and essential for the production of stable and mature messenger RNA
Functions:
Protection: from degradation by exonucleases.
Translation Initiation: recognized by the ribosome, translation initiation factors Absent in “G”
Transport: aids in the export of mRNA from nucleus to cytoplasm.
Capping Process:
A. RNA Triphosphatase: Removes one phosphate from the 5’ end of the
nascent RNA.
B. Guanylyltransferase: Adds a guanine monophosphate (GMP) to the 5’
end, creating a 5’ to 5’ triphosphate bridge.
C. Methyltransferase: Methylates the guanine at the 7th position.
Types of Caps:
A. Cap-0: The basic structure with a 7-methylguanosine.
B. Cap-1: Additional methylation at the 2’ position of the first nucleotide.
C. Cap-2: Further methylation at the 2’ position of the second nucleotide. 7-methylguanosine
 5’ capping

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 Poly-A Tailing
Addition of a multiple adenosine monophosphates, forming a stretch of RNA (poly(A) tail) to the 3’
end, typically of messenger RNA (mRNA) molecule
Functions:

1. Stability: protects mRNA from degradation by exonucleases.
2. Translation: increases translation efficiency by aiding in the recruitment of ribosomes.
3. Nuclear Export: export of mRNA from the nucleus to the cytoplasm.

Polyadenylation Process:

1. Cleavage: The 3’ end of the pre-mRNA is cleaved by CF-I & CF-II (Pre-mRNA cleavage factor)
2. Addition: Poly(A) polymerase adds adenine nucleotides to the cleaved 3’ end.

Regulation:

1. Alternative Polyadenylation: Different polyadenylation sites can be used within the same gene,
leading to the production of mRNA variants with different 3’ untranslated regions (UTRs)
2. Cell Type Specificity: The choice of polyadenylation sites can vary between different cell types and
conditions
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 Polyadenylation steps:
1. The processive polyadenylation complex binds to precursor mRNA
2. CPSF binds the complex 10–30 nucleotides downstream and cleaves the
3′-most portion
3. Polyadenylate polymerase enzyme polyadenylates the resulting end to form
the poly(A) tail by cleaving pyrophosphate from ATP & adding AMP units
to the RNA.
4. When the poly(A) tail reaches around 250 nucleotides in length, the
enzyme loses its ability to bind to CPSF and polyadenylation ceases, hence
dictating the length of the poly(A) tail.
5. CPSF interacts with RNA polymerase II, to stop transcription.
6. RNA polymerase II encounters a “termination sequence” (5’TTTATT3′ on the
DNA template and 5’AAUAAA3′ on the primary transcript).
 RNA Splicing
A process of mature mRNA formation by pre-mRNA processing by removing introns and joining exons

1. Spliceosome Complex:
a. a large and complex molecular machine, is responsible for the splicing process.
It consists of small nuclear RNAs (snRNAs) and a variety of associated protein
factors.
b. Key snRNAs involved include U1, U2, U4, U5, and U6, each playing a role in
different stages of splicing.
2. Splicing Sites:
a. Splicing occurs at specific sequences called splice sites. The 5' splice site
marks the beginning of an intron, while the 3' splice site marks the end.
b. The branch point, located within the intron, is crucial for the formation of the
lariat structure during splicing.
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 RNA Splicing
3. Splicing Mechanism:
a. The process begins with the recognition of the 5' splice site by the spliceosome.
b. The 5' end of the intron is cut, and the lariat structure is formed by the attachment of
the 5' end to the branch point.
c. The 3' end of the intron is then cut, and the exons are joined together, releasing the
intron as a lariat.

4. Alternative Splicing:
a. Alternative splicing allows a single gene to produce multiple mRNA variants by
including or excluding different exons.
b. This increases the diversity of proteins that can be produced from a single gene and
plays a key role in regulating gene expression and development.
 RNA Splicing
3. Regulation of Splicing:
a. Splicing is tightly regulated by various splicing factors and regulatory elements that
influence which splice sites are used.
b. Regulatory proteins can enhance or repress splicing of specific exons or introns,
contributing to the regulation of gene expression and cellular responses.

4. Disease Associations:
a. Aberrations in splicing can lead to various diseases, including some types of cancer
and genetic disorders such as cystic fibrosis and Duchenne muscular dystrophy.
b. Mutations in splice sites or splicing factors can disrupt normal splicing, leading to the
production of faulty or non-functional proteins.
References:

Fine Structure of Prokaryotic and Eukaryotic Genes:

Shafee, T., & Lowe, R. (2016). Eukaryotic and Prokaryotic Gene Structure.
https://papers.ssrn.com/sol3/papers.cfm?abstract_id=3013506

Structure and Function of Promoters in mRNA, rRNA, tRNA Genes:

Shine, M., Gordon, J., Schärfen, L., Zigackova, D., Herzel, L., & Neugebauer, K. M. (2024). Co-transcriptional gene
regulation in eukaryotes and prokaryotes. https://papers.ssrn.com/sol3/papers.cfm?abstract_id=3013506

RNA Polymerases in Prokaryotes and Eukaryotes: Types and Function:

RNA Transcription by RNA Polymerase: Prokaryotes vs
Eukaryotes.https://papers.ssrn.com/sol3/papers.cfm?abstract_id=3013506.

Transcription of mRNA, rRNA, and tRNA Genes in Prokaryotes and Eukaryotes:

Alberts, B., Johnson, A., Lewis, J., Raff, M., Roberts, K., & Walter, P. (2002). Molecular Biology of the Cell (4th ed.).
Garland Science. Chapter 6: “Transcription of RNA”.

Post-Transcriptional Processing of mRNA – 5’ Capping, Splicing, Polyadenylation, and RNA Editing:

Lodish, H., Berk, A., Kaiser, C. A., Krieger, M., Bretscher, A., Ploegh, H., Amon, A., & Martin, K. C. (2016). Molecular
Cell Biology (8th ed.). W.H. Freeman. Chapter 10: “RNA Processing”.
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Interesting Links:

1. Fine Structure of Prokaryotic and Eukaryotic Genes:
○ https://www.youtube.com/watch?v=xTnNv7YplSohttps://www.bing.com/videos/search?view=detail&q=cture+and+
Function+of+Promoters+in+mRNA%2c+rRNA%2c+tRNA+Genes+videos&&mid=11C3BFC986DFAE5743C711C3
BFC986DFAE5743C7&&FORM=VRDGAR
2. Structure and Function of Promoters in mRNA, rRNA, tRNA Genes:
○ https://www.bing.com/videos/search?view=detail&q=cture+and+Function+of+Promoters+in+mRNA%2c+rRNA%2c
+tRNA+Genes+videos&&mid=EF2ECA327348B98CC336EF2ECA327348B98CC336&&FORM=VRDGAR
3. RNA Polymerases in Prokaryotes and Eukaryotes: Types and Function:
○ https://www.bing.com/videos/search?view=detail&q=NA+Polymerases&&mid=05D1AAA02552B61A50DF05D1AA
A02552B61A50DF&&FORM=VRDGAR
4. Transcription of mRNA, rRNA, and tRNA Genes in Prokaryotes and Eukaryotes:
○ https://www.bing.com/videos/search?view=detail&q=NA+Polymerases&&mid=A55462E3F7957AAA1D09A55462E
3F7957AAA1D09&&FORM=VRDGAR
○ https://www.bing.com/videos/search?view=detail&q=NA+Polymerases&&mid=74808E17922E5F01E88574808E17
922E5F01E885&&FORM=VRDGAR
5. Post-Transcriptional Processing of mRNA – 5’ Capping, Splicing, Polyadenylation, and RNA Editing:
○ https://www.bing.com/videos/search?view=detail&q=Post-Transcriptional+Processing+of+mRNA+&&mid=D3D1EE
947EFF052C06D5D3D1EE947EFF052C06D5&&FORM=VRDGAR
○ https://www.bing.com/videos/search?view=detail&q=Post-Transcriptional+Processing+of+mRNA+&&mid=E0A191
A87B131368A2E0E0A191A87B131368A2E0&&FORM=VRDGAR

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Additional Information:

Touchon, M., & Rocha, E. P. (2016). Coevolution of the Organization and Structure of Prokaryotic
Genomes. Cold Spring Harbor perspectives in biology, 8(1), a018168.
https://doi.org/10.1101/cshperspect.a018168
Brown TA. Genomes. 2nd edition. Oxford: Wiley-Liss; 2002. Chapter 2, Genome Anatomies. Available
from: https://www.ncbi.nlm.nih.gov/books/NBK21120/
Berg, M. D., & Brandl, C. J. (2021). Transfer RNAs: diversity in form and function. RNA biology, 18(3),
316–339. https://doi.org/10.1080/15476286.2020.1809197
Pan, T. Modifications and functional genomics of human transfer RNA. Cell Res 28, 395–404 (2018).
https://doi.org/10.1038/s41422-018-0013-y
Corbett A. H. (2018). Post-transcriptional regulation of gene expression and human disease. Current
opinion in cell biology, 52, 96–104. https://doi.org/10.1016/j.ceb.2018.02.011
Zhao, B., Roundtree, I. & He, C. Post-transcriptional gene regulation by mRNA modifications. Nat Rev
Mol Cell Biol 18, 31–42 (2017). https://doi.org/10.1038/nrm.2016.132
Giudice, J., Jiang, H. Splicing regulation through biomolecular condensates and membraneless
organelles. Nat Rev Mol Cell Biol 25, 683–700 (2024). https://doi.org/10.1038/s41580-024-00739-7

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Question Bank:

Fine Structure of Prokaryotic and Eukaryotic Genes
1. What are differences between the fine structure of prokaryotic and eukaryotic genes?

2. How do introns and exons contribute to the complexity of eukaryotic genes?

3. Describe the role of operons in prokaryotic gene regulation.

4. What is the significance of the TATA box in eukaryotic gene promoters?

Structure and Function of Promoters in mRNA, rRNA, and tRNA Genes
1. How do promoters differ between mRNA, rRNA, and tRNA genes in prokaryotes?

2. What are the core promoter elements in eukaryotic mRNA genes?

3. Explain the role of upstream promoter elements in the transcription of rRNA genes.

4. How do enhancers and silencers affect promoter activity in eukaryotic genes?

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Question Bank:

RNA Polymerases in Prokaryotes and Eukaryotes: Types and Functions
1. Compare the types and functions of RNA polymerases in prokaryotes and eukaryotes.

2. What is the role of RNA polymerase I in eukaryotic cells?

3. How does RNA pol II differ from RNA polymerase III in terms of their transcriptional targets?

4. Describe the mechanism of transcription initiation by RNA polymerase in prokaryotes.

Transcription of mRNA, rRNA, and tRNA Genes
1. Outline the steps involved in the transcription of mRNA in eukaryotic cells.

2. How is the transcription of rRNA genes regulated in prokaryotes?

3. What are differences in the transcription of tRNA genes in prokaryotes and eukaryotes?

4. Explain the role of transcription factors in the transcription of eukaryotic mRNA genes.

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Question Bank:

Post-Transcriptional Processing of mRNA
1. What is the significance of 5’ capping in mRNA processing?

2. Describe the mechanism of splicing and its importance in mRNA maturation.

3. Explain the process of polyadenylation and its role in mRNA stability.

Application and Analysis
1. Analyze the impact of a mutation in the promoter region of a prokaryotic gene on its
expression.

2. Compare the efficiency of transcription between prokaryotic and eukaryotic systems and
discuss the factors influencing it.

3. Evaluate the consequences of defective splicing on gene expression and protein function.

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