RNA processing is the set of post-transcriptional modifications that produce a mature RNA molecule from a primary transcript in eukaryotic cells. This involves adding a 5' cap, polyadenylating the 3' end, and splicing out introns. Polyadenylation involves cleavage of the nascent RNA downstream of the AAUAAA sequence by ribonuclease, followed by addition of around 200 adenine nucleotides to the 3' end by poly(A) polymerase. The spliceosome, composed of small nuclear RNAs and proteins, facilitates splicing by binding to splice sites on the RNA and catalyzing transesterification reactions to remove introns and ligate exons.
2. RNA PROCESSING
Post-transcriptional Processing or RNA processing is a set of biological processes common
to mosteukaryotic cells by which anRNA primary transcript is chemically altered following
transcription from a gene to produce a mature, functional RNA molecule that can then leave the
nucleus and perform any of avariety of different functions in the cell. There are many types of
post-transcriptional modifications achieved through a diverse class of molecular mechanisms.
Phillip Sharp and RichardRoberts were awarded the 1993 Nobel Prize in Physiology or
Medicine for their discovery of introns and the splicing process
β’ In prokaryotes, no RNA processing is necessary: β the nascent RNA is usually the mRNA.
β’ In eukaryotes, the nascent RNA is called primary transcript-RNA β needs to be processed β
and transported to the cytoplasm for translation to occur.
β’ The processing steps are:
β Addition of a 5β 7-methyl guanosine cap (capping).
β Addition of a poly-A tail at the 3β end (polyadenylation)
β RNA splicing to remove intervening sequences (remove Introns
3.
4. TAILING
Eukaryotic RNA Processing: Polyadenylation
ο nascent RNA is cleaved downstream from the AAUAAA conserved sequence.
ο· By ribonuclease
ο The enzyme poly(A) polymerase adds adenine ribonucleotides
ο· up to 200 bases long at the 3β end of the RNA.
ο The poly(A) tail
ο· enhances the stability of eukaryotic mRNA and
ο· regulates its transport to the cytoplasmic Compartment
Polyadenylation:
Proteins required in mammals for cleavage
and polyadenylation of a new transcript.
Proteins required for efficient cleavage of pre-mRNA:
1. CPSF (cleavage & polyadenylation specificity factor), binds the AAUAAA
2. CstF (cleavage stimulation factor) binds to the G/U rich region cooperatively with CPSF
3. CFI and CFII (cleavage factors I and II), RNA-binding proteins
4. PAP (polyA polymerase)
5.
6. 5. nRNAP II (the CTD of the very large RPB1 subunit) stimulates cleavage
7. THE SPLICEOSOME
A spliceosome is a large and complex molecular machine found primarily within the nucleus
of eukaryotic cells. The spliceosome is assembled from small nuclear RNAs (snRNA) and
approximately 80 proteins. snRNAs (U1, U2, U4, U5 and U6) and associated proteins =
snRNPs
ο U1 binds to the GU sequence at the 5' splice site, along with accessory
proteins/enzymes,
ο U2 binds to the branch site, and ATP is hydrolyzed;
ο U5/U4/U6 trimer binds, and the U5 binds exons at the 5' site, with U6 binding to U2;
ο U1 is released, U5 shifts from exon to intron and the U6 binds at the 5' splice site;
ο U4 is released, U6/U2 catalyzes transesterification, U5 binds exon at 3' splice site,and
the 5' site is cleaved, resulting in the formation of the lariat;
ο U2/U5/U6 remain bound to the lariat, and the 3' site is cleaved and exons are ligated
using ATP hydrolysis. The spliced RNA is released and the lariatde branches.
Three types of short sequences dictate the precise cutting of the intron/exon boundaries - called
splice junctions.
ο Splice donor: 5β end of intron: exon-G-U
ο Splice Acceptor: 3β end of intron: A-G-exon
ο Branch site: within the intron, about 30 nucleotides upstream of the splice acceptor, has
an AT rich region with at least one A.