RNA Processing 2024 PDF

Summary

These notes provide a comprehensive overview of RNA processing, a crucial biological process. It explores the various types of RNAs, their processing steps, and the enzymes involved. The detailed information and examples presented make this a useful resource for students learning about RNA processing.

Full Transcript

RNA Processing
Molecular Biology and Genomics Course

Luisa Cochella, PhD
Multiple RNA species are at the heart of the
central dogma
snoRNA

rRN
snRNA A
DNA mRNA tRN Protein
A
miRNA

piRNA
siRNA
The central dogma within the cell
Nucleus:
DNA replication
Transcription
DNA replication
RNA
Transcription
processing
RNA
RNA decay
processing
Translation
RNA decay

Cytoplasm:
RNA
processing
Translation
Different RNA polymerases make distinct
products
Eukaryotes:

RNA pol I
rRNA

RNA pol II
mRNAs, snRNAs, snoRNAs, miRNAs

RNA pol III
tRNAs, 5S rRNA, U6, other small
RNAs
The product of transcription is only the
beginning

Primary Mature RNA
transcript
Cleavage
Splicing
Terminal nucleotide
addition
Editing (insertion,
deletion, modification)
Most RNAs require multiple processing
steps
Precursor Processing steps Mature

Polycistroni Multiple cleavage events 5S, 16S, 23S
c rRNA Nucleotide modifications (Bact.)
5.8S, 18S, 25S
(Euk.)
Precursor Cleavage, splicing, terminal tRNA
tRNA nucleotide addition (CCA), base
modifications
Pre-mRNA Capping, splicing, base mRNA
modifications, polyadenylation
Small RNA Endonuclease cleavage, exonuclease miRNAs, piRNAs,
Ribosomal RNA transcription, processing and
assembly are coupled
Ribosomal RNA (rRNA) transcription
Miller and Beatty
Science, 1969

10-44 kb regions, repeated in all genomes
“polycistronic” RNAs: enables equimolar production of various rRNAs
pol I transcripts (very strong promoter)
1% of genome but 40% of transcription
rRNA processing, a multi-step pathway

Co-transcriptional association with
processing factors and ribosomal
proteins (RPs)
Multiple endonucleases (and
exonucleases in higher eukaryotes)
release rRNAs
Dynamic association and dissociation of
processing factors as rRNAs fold and
bind RPs
Mostly in the nucleolus, some maturation
continues in the nucleoplasm
RNase III domains are key for processing rRNA
and other RNAs
Dimer of a bacterial RNase
III
dsRB
D RIIID

Mg2+ dependent endonucleases
Cleave dsRNA and intramolecular
stems (e.g. in pre rRNA, snoRNAs
and snRNAs)
dsRBD Leave 2 nt, 3′ overhangs
RIIID
Generate ends with 5′ PO4 and 3′ OH
Court DL et al. Annu Rev Genet 2013
Transfer RNA (tRNA) processing
CCA adding
RNaseP RNaseZ enzyme
removes 5′ removes adds new 3′ end
leader 3′ trailer
Various
nucleotide
modifying
enzymes

TSEN complex
excises introns
RNase P is a RNP and one of the first
discovered
Bacteria ribozymes
Archea * Eukarya

Wu J et al. Cell 2018 * by Sydney Altman, Norman Pace and
RNA processing enzymes enable a wealth of
applications

Xie K. et al. PNAS 2015
RNA processing enzymes enable a wealth of
applications

Xie K. et al. PNAS 2015
Key Points
Precise ends of mature mRNAs and tRNAs (and most RNAs)
are generated by cleavage by RNases
Ends are primarily defined by endonucleases, but
exonucleases can be used to refine them
Many RNases rely on structure for specificity
3′ terminal nucleotide addition and removal of intervening
sequences is important for tRNA maturation
RNases (and other RNA processing enzymes) can be
repurposed for diverse applications
rRNAs and tRNAs have many modified
nucleotides
Human 28S rRNA Human
tRNA
Ribonucleotides can be modified in >100
manners
Base
modifications

Ribose
modifications
Nucleotide modifications have diverse
consequences
Modulation of base-pairing & Structure Binding of specific
decoding stabilization “readers”

2′OMe affects structure and
stability
Guiding modification specificity on rRNA
Methyltransferase PseudoU synthase
Nop1p/fibrillarin Cbf5p/dyskerin

snoRNPs
(snoRNAs +
proteins)
tRNA modifying enzymes use structure and sequence
for specificity

Pseudo Uridine
Synthases (PUS)
Methyltransferases
(TRMT, NSUN, METTL)
Adenosine Deaminases
(ADAT)

Chujo & Tomizawa. FEBS
Key Points
Large fractions of nucleotides in rRNA and tRNA are post-
transcriptionally modified (up to 25% in tRNA!)
Methylation of the 2′ OH and pseudouridylation are the
most common, but there’s a large diversity
Specificity of rRNA modifications is determined by base
pairing interactions with snoRNAs that guide respective
enzymes
Specificity of tRNA modifications relies primarily on global
and local structure. These modifications can be very
elaborate and require a series of steps
Nucleotide modifications affect structure, stability and the
ability to interact with other RNAs and proteins
Most RNAs require multiple processing
steps
Precursor Processing steps Mature

Polycistroni Multiple cleavage events 5S, 16S, 23S
c rRNA Nucleotide modifications (Bact.)
5.8S, 18S, 25S
(Euk.)
Precursor Cleavage, splicing, terminal tRNA
tRNA nucleotide addition (CCA), base
modifications
Pre-mRNA Capping, splicing, base mRNA
modifications, polyadenylation
Small RNA Endonuclease cleavage, exonuclease miRNAs, piRNAs,
Eukaryotic messenger RNA (mRNA)
processing

Pre-mRNA Mature
5′ capping mRNA
Splicing
3′ cleavage &
polyadenylation
Base modifications
Pre-mRNA capping
mRNA 3′ end formation: cleavage &
polyadenylation
CPSF

CstF

PABP
A convenient handle for mRNA enrichment

*Only ~3% of total
cellular RNA is mRNA
Histone mRNA 3′ end formation - an
important
Histone exception
mRNAs lack polyA tail
Are short lived and regulated by cell cycle
3′ end stem loop is generated by U7 snRNP-mediated reaction
Stem loop bound by SLBP
Roles of the 5′ cap and polyA tail
Help direct downstream maturation including
splicing and transcription termination
Important for transport to cytoplasm
Stabilize mRNA
Important for translation initiation

Gallie DR. Genes & Dev, 1991
Key Points

mRNA ends are defined by capping and cleavage &
polyadenylation
These are necessary for stability but also for downstream
events
Defining features of mRNAs are helpful for biochemical
distinction from other RNAs for downstream analysis
Pre-mRNA splicing

Chicken alpha 2 (type I) collagen
gene
37 Kb, >50 introns

Ohkubo H et al. PNAS 1980
*Richard Roberts and Phil Sharp won the Nobel Prize for this
Intron content differs substantially across
species
~228 total introns in yeast
% of genes with X
introns

human Titin gene has 363
introns!
human Dystrophin gene has
Number of introns 79 introns (98% of its 2.4 mb)
Intron lengths differ substantially across
species

yeast genes have infrequent short introns
human genes have short exons and frequent long introns
What makes an
intron?
The splicing reaction

sequential trans-esterification reactions
products are ligated exons and a branched lariat (2’5’) intron
 The spliceosome catalyzes pre-mRNA splicing

The spliceosome is composed of five snRNPs

And two other protein complexes

Plaschka et al. Cold Spring Harb Perspect Biol, 2019
Spliceosome assembly begins with U1 and U2
binding
U1

U
2
The spliceosome is dynamically assembled over
every intron
U1

U
2

Multiple helicases (using energy
from ATP) enable large
rearrangements of RNA:RNA
interactions
The spliceosome is dynamically assembled over
every intron

Plaschka, Lin & Nagai. Nature, 2017
Consensus sequences are necessary but not
sufficient…
Exonic splicing enhancers
(ESEs) are recognized by SR
proteins (Ser/Arg rich proteins
with RRM domains)

Intronic Splicing Enhancers (ISEs)

Exonic and Intronic Splicing
Silencers (ESSs and ISSs) have
regulatory roles and help avoid
use of cryptic sites – often bound
by hnRNPs (heterogeneous
ribonucleoprotein particles)
An important consequence of splicing: EJC
deposition

EJC = Exon Junction
Complex
a “mark” of correct splicing
The spliceosome is yet another remnant of the
RNA world
group I introns group II introns pre-mRNA introns
Bacteria Bacteria Eukaryotes
Archea Archea
Fungal/plant Fungal/plant mitochondria
mitochondria and chloroplasts
and chloroplasts
Self-splicing Spliceosome-mediated
Self-splicing Requires ATP (helicases)
Requires GTP
Intron-lariat intermediate Intron-lariat intermediate
Linear intermediate

Common ancestor
Key Points
Introns are common in eukaryotic genes and must be removed from
pre-mRNA to produce mRNA
Introns are marked by a 5’ splice site, branch point sequence, and 3’
splice site
Splicing proceeds in a two-step transesterification reaction
The spliceosome catalyzes intron removal
Splicing is a multi-step process involving more than 80 proteins, and 5
snRNAs
RNA helicases and step-specific splicing factors assist with remodeling
of the protein and RNA network during the different steps
The spliceosome is a protein directed ribozyme
Alternative processing is frequent and plays
regulatory roles
Alternative splicing – skipped exon

Alternative 5’ splice site

Alternative 3’ splice site

Alternative transcriptional start site

Alternative polyadenylation site
 Extreme cases of alternative processing
rosophila Dscam (Down syndrome cell adhesion molecule)
38,016 splice isoforms

Mammalian Pcdh (Clustered protocadherins)
Multiple alternative initiation isoforms

Jin & Li. Cell Mol Life Sci, 2018
Splicing control – a game changing therapy
Spinal Muscular Atrophy (SMA)
is caused by low SMN levels

*SMN is a chaperone
that facilitates
assembly of snRNPs Work from Adrian Krainer, Ravindra Singh and Elliot Androphy’s la
Splicing control – a game changing therapy

Modified backbones
for stability,
specificity and
delivery

First FDA approved drug
for SMA treatment

Hua et al. (Krainer lab). AJHG, 2008
Key Points
Alternative processing (splicing, initiation or cleavage and
polyadenylation) are common and result in multiple isoforms per gene
These processes have been particularly exploited to enable
complexity of the nervous system
Splice site selection requires positive and negative regulators, in
addition to the necessary consensus sequences. These additional
elements can be regulated to result in alternative spliced mRNAs
The speed of transcription also affects splice site selection
It is possible to manipulate splicing with antisense oligos for therapy.
But also with small molecules! (current therapy for SMA is the small
molecule Risdiplam)
Eukaryotic mRNAs also carry modified
nucleotides

tRNA modifying
enzymes

ADAR1: mostly editing of
endogenous dsRNA prevents
immune activation
ADAR2: Specific editing events
recode important mRNAs (e.g.
mRNA modifications enable self vs. non-self
recognition

Production of a
pro-inflammatory
cytokine

Markers of immune cell
activation

Karikó, Buckstein, Ni & Weissman. Immunity, 2005
Key Points
Base modifications are also common in mRNA
Editing by ADARs is best understood
m6A is abundant and many functions have been proposed
Other modifications are less abundant and may represent “spill over”
activity from tRNA modifying enzymes
Multiple modifications seem to mark mRNAs as “self” to prevent
immune activation
Most RNAs require multiple processing
steps
Precursor Processing steps Mature

Polycistroni Multiple cleavage events 5S, 16S, 23S
c rRNA Nucleotide modifications (Bact.)
5.8S, 18S, 25S
(Euk.)
Precursor Cleavage, splicing, terminal tRNA
tRNA nucleotide addition (CCA), base
modifications
Pre-mRNA Capping, splicing, base mRNA
modifications, polyadenylation
Small RNA Endonuclease cleavage, exonuclease miRNAs, piRNAs,
Completing the RNA life cycle – RNA decay

Transcriptio Translation
n
DNA mRNA Protein

Decay Decay
RNA decay has different purposes and uses distinct
mechanisms

RNA turnover to maintain steady-state or
for regulatory purposes

Degradation of defective RNAs (quality
control pathways)

Removal of foreign RNA (CRISPR, RNAi,
protein-based foreign RNA recognition)
Average half-lives of different RNA
molecules
Bacterial mRNA decay

Belasco. Nat Rev Mol Cell Biol, 2010
Eukaryotic mRNA decay

*Rates of deadenylation can
be regulated by mRNA
structure or sequence
mostly at the 3’UTR (protein
or miRNA binding sites)

Passmore & Coller. Nat Rev MCB, 2021
Key Points
RNA decay is critical to steady-state RNA levels (and is tightly
regulated)
Bacterial mRNA decay needs endonucleolytic cleavage
Eukaryotic mRNA decay begins with deadenylation, followed by
decapping and finally exonucleolytic cleavage from the ends (XRN1
and exosome)
The rate of deadenylation and decapping can be regulated by 3’ UTR
structure and sequence (through binding to other factors)
Consequences of RNA processing

Production of functional RNAs and RNPs

But also…
Opportunity for regulation (concentration,
rate)
Generation of molecular diversity
Biogenesis quality control
Why is eukaryotic gene expression so
complex?

Evolution of organismal complexity is a tempting answer,
but:

All of these mechanisms appeared in unicellular
eukaryotes…
Massive abundance of prokaryotes says these
“embellishments” are not necessary for the central
dogma per se
A hypothesis for the evolution of this
complexity Chromatin obstructs transcription (and
restricts access to DNA)
A nuclear envelope acts as a gatekeeper
of the genome
Splicing, capping, polyadenylation are
necessary for nuclear export and
translation (i.d. cards for endogenous
mRNAs)
RNA modifications mark endogenous RNA

They likely evolved as part of an
arms race against genomic
Madhani H. The frustrated gene. Cell, 2013
parasites!