PBEC 306 Small RNA Biology & Epigenetics Lecture 1 2024 PDF

Summary

Lecture 1 of PBEC 306, covering Small RNA Biology & Epigenetics class in 2024. The course covers different units, such as chromatin modeling and remodeling and small RNA pathways. This document is not an exam paper.

Full Transcript

PBEC 306

SMALL RNA BIOLOGY & EPIGENETICS

LECTURE I

2024
 Course Contents
 Unit 1: Chromatin Modeling and Remodeling -- Polycomb complexes,
SWI/SNF1 complexes and other chromatin modifiers.
 Unit 2: Interpretation of DNA Methylation Marks by Cellular Machinery --
Study of methylated DNA binding proteins, their structure and function, methods
of altering DNA methylation.
 Unit 3: Study of Histone Modifications -- Histone modifications, modifying
enzymes, histone deacetylase inhibitors.
 Unit 4: Chromatin Modification and Development -- Effect on somatic
embryogenesis, leaf development, photosynthesis, flowering and ageing.
 Unit 5: Epigenetics and Environment -- Role in plant stresses, epigenetic
memory.
 Unit 6: Epigenetics in Human Systems -- Role in immune response, cancer
and cardiovascular diseases.
 Unit 7: Non-coding RNAs -- Types and occurrence of non-coding RNAs, small
RNAs in different biological systems, diversity and evolution of small RNAs.
 Unit 8: Identification and Characterization of Small RNAs -- Discovery,
detection and validation of small RNAs, target prediction and validation,
databases on small RNAs, an overview of bioinformatics tools in small RNA
biology.
 Unit 9: Small RNA Pathways - Biogenesis of different classes of small RNAs,
components and their characteristic features.
 Unit 10: Regulation of Gene Expression by Small RNAs -- Transcriptional
gene silencing (TGS), Post-transcriptional Gene Silencing (PTGS), gene
activation, evolutionary transition of small RNA-target gene pair.
 Unit 11: Biological Processes Regulated by Small RNAs -- Diverse roles of
small RNAs in regulating biological processes in different organisms: bacteria,
plants & animals, trans-kingdom cross-talk mediated by small RNAs.
 Unit 12: Small Non-coding RNAs as Effective Tools in Biotechnology --
amiR technology, siRNA technology, Virus-induced gene silencing (VIGS), RNA
Interference (RNAi) and RNA activation (RNAa), target mimicry, Short tandem
target mimic technology (STTM) & miR sponges, CRISPR-Cas mediated
genome editing technology, crop improvement, diagnostics and therapeutic
applications in human diseases.
 Unit 13: Hands-on Training -- Techniques for studying differential methylation
of DNA, gene expression in response to altered DNA methylation, expression
profiling of small RNAs, survey of small RNA databases, case studies of plant
miRNA families.
Central Dogma of Molecular Biology

Storehouse

Transmitter

Workhorse
Central Dogma: Original Version By Crick

An Unpublished Note by Francis Crick in 1956

Molecular Cell. 2023; 83(3):315
It’s RNA World, After all !

Storehouse

Transmitter
Catalytic activity
Gene Regulators
Messenger
Enzyme Activity
Regulators
Workhorses
 Outline of Today’s Lecture

1. Introduction to non-coding RNAs

2. Housekeeping non-coding RNAs

3. Regulatory non-coding RNAs

Small nc RNAs
 Non-coding RNAs
A ncRNA is the functional RNA molecule that is transcribed from DNA, but not
translated into proteins.

Different types of ncRNAs are known which are generally classified as:
 Housekeeping Non-coding RNAs

Housekeeping ncRNAs are abundantly and ubiquitously expressed RNAs that
regulate generic cellular functions.

They include rRNAs, tRNAs, snRNAs, snoRNAs, TERC.

Usually small, ranging in size from 50 to 500 nucleotides long (except rRNAs).

Generally constitutively expressed in all cell types and necessary for cell viability.
 Ribosomal RNAs or rRNAs
Most abundant class of RNAs in most cells, comprising approximately 80% of the
cellular transcriptome.

Ribosomes are remarkable ribonucleoprotein complexes that are responsible for
protein synthesis in all forms of life. They polymerize polypeptide chains
programmed by nucleotide sequences in messenger RNA in a mechanism mediated
by transfer RNA.

rRNAs serve as the essential binding site for ribosomal proteins within the
assembled ribosome and contribute to the binding of extra-ribosomal factors and
ribosome-associated proteins, resulting in the protein translation machinery.

rRNAs were discovered during cell fractionation experiments. The subunits of
ribosome and rRNAs were detected through differential centrifugation and that’s why
they are identified by their rate of sedimentation (Svedberg coefficient).
 Ribosomal RNAs or rRNAs
Ribosomes are made up of large and small
subunits and these two units come together for
mRNA translation.

Prokaryotes: rRNA of ~1500 nt in length with a
Svedberg coefficient of 16S. Together with
ribosomal proteins, the small subunit is of 30S.
Large subunit has two rRNA molecules: one of
approximately 2900 nt (23S) and the second
one is shorter in length approximately 120 nt
(5S). These two rRNAs together with proteins
gives rise of large 50S subunit.
Eukaryotes: Ribosomes are made of 60S
and 40S subunits. Two short rRNA
molecules less than 200 nt in length (5S
and 5.8S) and two longer RNA molecules:
one over 5 kb (28S) and another of nearly
2 kb (18S). Eukaryotic ribosome is of 80 S.
In addition to this, eukaryotic cells have
rRNA in mitochondria and chloroplasts.
 Importance of rRNAs
1. Protein translation: The primary function of rRNA is in protein synthesis – in
binding to messenger RNA and transfer RNA to ensure that the codon sequence of the
mRNA is translated accurately into amino acid sequence in proteins and facilitate the
process of translation.
To achieve this, rRNA has a distinctive three-dimensional shape involving internal
loops and helices that creates specific sites within the ribosome – the A, P and E sites.
The P (peptidyl site) site is for binding a growing polypeptide, the A site (aminoacyl
site) anchors an incoming tRNA charged with an amino acid (aminoacyl tRNA). After
peptide bond formation, the tRNA binds briefly to the E site (exit site) before leaving
the ribosome. In addition rRNA also has sites for binding to some ribosomal proteins
and careful analysis has demarcated the exact residues in both the RNA and protein.
2. Evolutionary and diversity Studies: Ribosomal RNA are also expressed in every
cell of all extant species. The sequence of the core catalytic sites are also highly
conserved making rRNA an excellent tool for the study of taxonomy and phylogenetics.
There is a difference in the rate of evolution of residues on the surface and interior of
rRNA, and nucleotides involved in core catalytic activity, such as in the formation of a
peptide bond, appear to have predated the appearance of life on earth. The extent to
which two species differ in rRNA sequences can give a good estimate of their
evolutionary distance.
The 16S rRNA has become the molecular standard or taxonomic genomic marker in
studying evolutionary relationships between almost all bacteria and archaea. The
marker allows one to examine genetic diversity in microbial communities, specifically
what microbes are present in a sample. However, the 23S rRNA has followed a very
similar (if not identical) evolutionary path. The 23S rRNA therefore provides additional
complementary data that can be tapped to study the evolution of the ribosome.

The 16S and 23S rRNAs each have a high degree of sequence
Identity with 30–40% of the well aligned positions between bacteria
and archaea being conserved. Yet despite this large degree of
identity, there are significant phylogenetic signals in the pattern of
change of the remaining nucleotides that can reveal
the evolutionary history of the molecules.
2-D structure of 16Sr rRNA. The length and position of stem-
loops are very similar in different species, although the exact
sequence may vary at several positions.
 Ribosomal RNA sequences differ between species, due to mutation: The
ribosome is an ancient and essential component of cellular organisms, and its form
and function is consistent across the spectrum of living things. A key aspect of
ribosomes and ribosomal RNAs is that their function is very highly “conserved”, or
maintained by natural selection, between and among species. However, the
molecules that make up the ribosome, including the ribosomal RNAs, differ subtly
between species in their composition, due to differences (caused by mutation) in the
sequences of the genes that encode them.

Through variation in rRNA sequences we can distinguish organisms on
approximately the species level and trace evolutionary relationships.
However, the exact sequences of DNA that encode these
components are not identical between organisms. Slight
differences in the DNA sequence encoding these
molecules can arise without altering their shapes
significantly, and thus without affecting their function. The
end result is that, over evolutionary time, organisms very
slowly accumulate changes in the sequences of the genes
that encode parts of the ribosome.
3. rRNA as Targets of antibiotics: rRNA
is the most commonly exploited RNA target
for small molecules. The bacterial ribosome
comprises 30S and 50S RNP subunits,
contains a number of binding sites for novel
anti-bacterial agents. The large difference
between prokaryotic and eukaryotic rRNA
16S rRNA
enables rRNA-targeting against a broad
spectrum of pathogenic bacteria.
X-ray crystallography studies have
elucidated many antibiotic-binding sites on
the ribosomal subunit facilitating the design
of novel antibiotics.
It has also been shown that antibiotic
resistance often stems from point
mutations in these binding sites. For
instance, the resistance of Euglena and E.
coli to streptomycin stems from mutation in
the 16S rRNA sequence. Similar results
were found for the resistance of
Streptomyces to Spectinomycin.

23S rRNA
4. Regulatory RNAs from rRNAs: In a new dimension to the function of rRNA, its
precursors (pre-ribosomal RNA) have been implicated in the generation of micro RNA
that mediate inflammation and cardiac disease in response to mechanical stress. The
mechanisms of this activity are still being elucidated.
For eg. miR-712 is generated from murine pre-ribosomal RN45S. This gene encodes
for 45S which contains sequences for 18S, 5.8S and 28S rRNA with two intervening
sequences. It is generated in DICER1-dependent manner and it induces endothelial
inflammation and atherosclerosis (major underlying cause of cardiovascular
pathologies and preferentially occurs in arterial regions) (Son et al., 2013; Nat Comm.
4, 3000).
 Small Nuclear RNAs or snRNAs
snRNAs are