Transcript Slide

• Small RNAs and their regulatory
roles.
Presented by:
Chirag Nepal
Papers to be discussed
Tiny RNAs associated with transcription start sites in
animals.
– Nat Genet. 2009 May;41(5):572-8. Epub 2009 Apr 19.
Nuclear-localized tiny RNAs are associated with
transcription initiation and splice sites
in metazoans.
– Nat Struct Mol Biol. 2010 Aug;17(8):1030-4. Epub 2010 Jul
11.
Introduction
• Small RNAs are involved in many biological and cellular
processes.
• Previously discovered short RNAs that map to promoter
region.
– Yeast (250-500 nt )
– Arabidopsis (variable size)
– PASRs in mammalian transcriptome (<200 nt)
• Explore the nature of small RNAs that map to promoter
regions.
– Examined deep-sequencing libraries from human, chicken and
Drosophila.
– Identified a new class of small RNAs that are predominantly 18
nt in length, derived near the 5’ end of transcribed genes.
Identification of tiRNAs
Are these tiRNAs degraded products ?
Genomic Distribution of tiRNA
 Identified 2,312 human tiRNAs.
 Predominantly downstream of highly expressed
deepCAGE tag in a promoter.
 Identified 1,186 tiRNAs in chicken.
 tiRNA discovery is dependent on the sequencing depth.
RNAs are most abundant at -60 nt to +120 nt relative to TSS, mostly on the
same strand as the TSS.
tiRNAs loci express bidirectional transcripts.
• tiRNAs are not truncated or degraded 5’ ends of
highly expressed capped transcripts.
• Found almost exclusively downstream of TSS.
Size distribution of tiRNAs
tiRNAs at 5’ end
tiRNAs at 3’ end
Gene and tiRNA expression
Relative gene expression of all
human genes with tiRNA (1,318 tiRNAs,
947 genes) with 3,368 Refseq genes
that do not have tiRNAs
Relative gene expression of chicken
genes with tiRNA and without tiRNAs.
*P <0.01, **P <0.001, ***P< 0.0001
tiRNA and deepCAGE abundance do not
exhibit linear relationship
Gene Ontology terms are consistent
with high expression.
Do promoters with tiRNAs show enrichment for
genomic features of active transcription ?
Examine the loci for evidence
of H3K9 acetylation, binding
of RNA pol II, and TF Sp1 and
Pu.1 in THP-1 cells.
 Enrichment for binding of
RNA pol II and Sp1.
No enrichment for H3K9
acetylation or PU.1 binding.
Discussion
A new class of small RNA, 18 nt in length, adjacent to TSS.
Show similarities with previously described PASRs
Low abundance, distribution skewed to 3’ of TSS
Occurrence in more than one organism
Associated with highly expressed genes and GC rich
But vary significantly in size length (70 nt).
Are tiRNAs simply signatures of transcription or have a
particular function ?
Evolutionary conserved, non random distribution and distinct
size characteristics indicate they are not random noise but a
new and distinctive size of RNA centrally associated with
transcription.
 High-throughput RNA sequencing have led to detection of
new members of established classes of small RNAs and many
novel RNAs.
 Discovery and characterization of at least 3 classes of
promoter proximal RNAs:
– 5’ capped promoter-associated small RNAs (PASRs)
– Transcription start site (TSS)-associated RNAs (Tssa RNAs)
– Transcription initiation RNAs (tiRNAs)
 Performed deep sequencing of small RNAs from the nuclear
and cytoplasmic fractions of human monocytic leukemia cell
(THP-1) and nuclei of primary mouse granulocytes.
– Determine the sub cellular localization of tiRNAs and possibility of
other classes of nuclear-enriched small RNAs.
tiRNAs are localized in the nucleus
Assessed relative nuclear enrichment of tiRNAs by analysis of THP-1 nucleus and
cytoplasmic.
tiRNAs are > 40 fold enriched in the nucleus.
nuclear RNAs (7,014 Refseq genes), cytoplasmic (914)
Genes with tiRNAs derived from both RNAs are more
expressed.
Features of nuclear-localized small RNAs
Extensive S/AS cluster proximal to TSS
Peak tiRNAs and RNA Pol II density lies at the same position upstream of the +1 nucleosome.
tiRNAs show enrichment for 3’-terminal guanines in THP-1 cells.
Enrichment of 3’-terminal guanines even in chicken
and Drosophila
tiRNAs are enriched at transcription-initiation chromatin
marks
Two fold enriched for chromatin marks (derived from CD4+ cells)
Splice-site RNAs are associated with splice donor
sites
35 fold enriched in nuclear deep sequencing library (present in internal exons as well).
Splice-site RNAs are found in wide range of evolutionary distant metazoans.
MicroRNA-offset RNAs are nuclear enriched
MicroRNA-offset RNAs (moRNAs) are conserved small RNAs derived from the ends
of pre-miRNAs.
moRNAs from 60 pre-miRNAs are mostly derived from 5’ arm, regardless of processed
mature miRNAs, suggesting moRNAs and miRNA biogenesis may be linked but not
interdependent.
Select miRNAs are nuclear enriched in THP-1 cells
Most miRNAs are cytoplasmically localized, while expression profiling revealed a
small subset of miRNAs is also nuclear enriched.
Down regulation of the miR-15/16 cluster has been associated with chronic
lymphocytic lymphoma, prostate carcinoma and targets multiple oncogenes,
including BCL2, MCL1, CCND1 and WNT3A.
miR-15/16 might have additional nuclear functions or might interact with target
within the nucleus.
sdRNAs show differential subcellular localization
snoRNAs, which are classified as either C/D or H/ACA, can be processed into snoRNA-derived
RNAs (sdRNAs) with distinct size distributions.
Consistent with snoRNA localization to the nucleolus, C/D sdRNAs are 3- to 200-fold enriched
in the THP-1 nuclear fraction.
However, sdRNAs from two H/ACA snoRNAs, SNORA36B and SNORA63, which are miRNA-like
and are predominantly ~22 nt in length, are approximately 3-fold enriched in the cytoplasm.
 These data indicate that the boundary between miRNAs and other small RNAs, particularly
H/ACA sdRNAs, may be blurry.
Discussion
Wide range of small RNAs localized to, and
abundant in the metazoan nucleus.
Many of these RNAs might be involved in
regulating epigenomic modifications and
transcription.
• Thank you !