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Polyadenylation

January 08, 2023

Polyadenylation is the addition of a poly(A) tail to an RNA transcript, typically a messenger RNA (mRNA). The poly(A) tail consists of multiple adenosine monophosphates; in other words, it is a stretch of RNA that has only adenine bases. In eukaryotes, polyadenylation is part of the process that produces mature mRNA for translation. In many bacteria, the poly(A) tail promotes degradation of the mRNA. It, therefore, forms part of the larger process of gene expression.

Typical structure of a mature eukaryotic mRNA

The process of polyadenylation begins as the transcription of a gene terminates. The 3′-most segment of the newly made pre-mRNA is first cleaved off by a set of proteins; these proteins then synthesize the poly(A) tail at the RNA's 3′ end. In some genes these proteins add a poly(A) tail at one of several possible sites. Therefore, polyadenylation can produce more than one transcript from a single gene (alternative polyadenylation), similar to alternative splicing.[1]

The poly(A) tail is important for the nuclear export, translation and stability of mRNA. The tail is shortened over time, and, when it is short enough, the mRNA is enzymatically degraded.[2] However, in a few cell types, mRNAs with short poly(A) tails are stored for later activation by re-polyadenylation in the cytosol.[3] In contrast, when polyadenylation occurs in bacteria, it promotes RNA degradation.[4] This is also sometimes the case for eukaryotic non-coding RNAs.[5][6]

mRNA molecules in both prokaryotes and eukaryotes have polyadenylated 3′-ends, with the prokaryotic poly(A) tails generally shorter and fewer mRNA molecules polyadenylated.[7]

Background on RNA

Further information: RNA and Messenger RNA
 
Chemical structure of RNA. The sequence of bases differs between RNA molecules.

RNAs are a type of large biological molecules, whose individual building blocks are called nucleotides. The name poly(A) tail (for polyadenylic acid tail)[8] reflects the way RNA nucleotides are abbreviated, with a letter for the base the nucleotide contains (A for adenine, C for cytosine, G for guanine and U for uracil). RNAs are produced (transcribed) from a DNA template. By convention, RNA sequences are written in a 5′ to 3′ direction. The 5′ end is the part of the RNA molecule that is transcribed first, and the 3′ end is transcribed last. The 3′ end is also where the poly(A) tail is found on polyadenylated RNAs.[1][9]

Messenger RNA (mRNA) is RNA that has a coding region that acts as a template for protein synthesis (translation). The rest of the mRNA, the untranslated regions, tune how active the mRNA is.[10] There are also many RNAs that are not translated, called non-coding RNAs. Like the untranslated regions, many of these non-coding RNAs have regulatory roles.[11]

Nuclear polyadenylation

Function

In nuclear polyadenylation, a poly(A) tail is added to an RNA at the end of transcription. On mRNAs, the poly(A) tail protects the mRNA molecule from enzymatic degradation in the cytoplasm and aids in transcription termination, export of the mRNA from the nucleus, and translation.[2] Almost all eukaryotic mRNAs are polyadenylated,[12] with the exception of animal replication-dependent histone mRNAs.[13] These are the only mRNAs in eukaryotes that lack a poly(A) tail, ending instead in a stem-loop structure followed by a purine-rich sequence, termed histone downstream element, that directs where the RNA is cut so that the 3′ end of the histone mRNA is formed.[14]

Many eukaryotic non-coding RNAs are always polyadenylated at the end of transcription. There are small RNAs where the poly(A) tail is seen only in intermediary forms and not in the mature RNA as the ends are removed during processing, the notable ones being microRNAs.[15][16] But, for many long noncoding RNAs – a seemingly large group of regulatory RNAs that, for example, includes the RNA Xist, which mediates X chromosome inactivation – a poly(A) tail is part of the mature RNA.[17]

Mechanism

Proteins involved:[12][18]

CPSF: cleavage/polyadenylation specificity factor
CstF: cleavage stimulation factor
PAP: polyadenylate polymerase
PABII: polyadenylate binding protein 2
CFI: cleavage factor I
CFII: cleavage factor II

The processive polyadenylation complex in the nucleus of eukaryotes works on products of RNA polymerase II, such as precursor mRNA. Here, a multi-protein complex (see components on the right)[18] cleaves the 3′-most part of a newly produced RNA and polyadenylates the end produced by this cleavage. The cleavage is catalysed by the enzyme CPSF[13][18] and occurs 10–30 nucleotides downstream of its binding site.[19] This site often has the polyadenylation signal sequence AAUAAA on the RNA, but variants of it that bind more weakly to CPSF exist.[18][20] Two other proteins add specificity to the binding to an RNA: CstF and CFI. CstF binds to a GU-rich region further downstream of CPSF's site.[21] CFI recognises a third site on the RNA (a set of UGUAA sequences in mammals[22][23][24]) and can recruit CPSF even if the AAUAAA sequence is missing.[25][26] The polyadenylation signal – the sequence motif recognised by the RNA cleavage complex – varies between groups of eukaryotes. Most human polyadenylation sites contain the AAUAAA sequence,[21] but this sequence is less common in plants and fungi.[27]

The RNA is typically cleaved before transcription termination, as CstF also binds to RNA polymerase II.[28] Through a poorly understood mechanism (as of 2002), it signals for RNA polymerase II to slip off of the transcript.[29] Cleavage also involves the protein CFII, though it is unknown how.[30] The cleavage site associated with a polyadenylation signal can vary up to some 50 nucleotides.[31]

When the RNA is cleaved, polyadenylation starts, catalysed by polyadenylate polymerase. Polyadenylate polymerase builds the poly(A) tail by adding adenosine monophosphate units from adenosine triphosphate to the RNA, cleaving off pyrophosphate.[32] Another protein, PAB2, binds to the new, short poly(A) tail and increases the affinity of polyadenylate polymerase for the RNA. When the poly(A) tail is approximately 250 nucleotides long the enzyme can no longer bind to CPSF and polyadenylation stops, thus determining the length of the poly(A) tail.[33][34] CPSF is in contact with RNA polymerase II, allowing it to signal the polymerase to terminate transcription.[35][36] When RNA polymerase II reaches a "termination sequence" (⁵'TTTATT3' on the DNA template and ⁵'AAUAAA3' on the primary transcript), the end of transcription is signaled.[37] The polyadenylation machinery is also physically linked to the spliceosome, a complex that removes introns from RNAs.[26]

Downstream effects

The poly(A) tail acts as the binding site for poly(A)-binding protein. Poly(A)-binding protein promotes export from the nucleus and translation, and inhibits degradation.[38] This protein binds to the poly(A) tail prior to mRNA export from the nucleus and in yeast also recruits poly(A) nuclease, an enzyme that shortens the poly(A) tail and allows the export of the mRNA. Poly(A)-binding protein is exported to the cytoplasm with the RNA. mRNAs that are not exported are degraded by the exosome.[39][40] Poly(A)-binding protein also can bind to, and thus recruit, several proteins that affect translation,[39] one of these is initiation factor-4G, which in turn recruits the 40S ribosomal subunit.[41] However, a poly(A) tail is not required for the translation of all mRNAs.[42] Further, poly(A) tailing (oligo-adenylation) can determine the fate of RNA molecules that are usually not poly(A)-tailed (such as (small) non-coding (sn)RNAs etc.) and thereby induce their RNA decay.[43]

Deadenylation

In eukaryotic somatic cells, the poly(A) tails of most mRNAs in the cytoplasm gradually get shorter, and mRNAs with shorter poly(A) tail are translated less and degraded sooner.[44] However, it can take many hours before an mRNA is degraded.[45] This deadenylation and degradation process can be accelerated by microRNAs complementary to the 3′ untranslated region of an mRNA.[46] In immature egg cells, mRNAs with shortened poly(A) tails are not degraded, but are instead stored and translationally inactive. These short tailed mRNAs are activated by cytoplasmic polyadenylation after fertilisation, during egg activation.[47]

In animals, poly(A) ribonuclease (PARN) can bind to the 5′ cap and remove nucleotides from the poly(A) tail. The level of access to the 5′ cap and poly(A) tail is important in controlling how soon the mRNA is degraded. PARN deadenylates less if the RNA is bound by the initiation factors 4E (at the 5′ cap) and 4G (at the poly(A) tail), which is why translation reduces deadenylation. The rate of deadenylation may also be regulated by RNA-binding proteins. Additionally, RNA triple helix structures and RNA motifs such as the poly(A) tail 3’ end binding pocket retard deadenylation process and inhibit poly(A) tail removal.[48] Once the poly(A) tail is removed, the decapping complex removes the 5′ cap, leading to a degradation of the RNA. Several other proteins are involved in deadenylation in budding yeast and human cells, most notably the CCR4-Not complex.[49]

Cytoplasmic polyadenylation

There is polyadenylation in the cytosol of some animal cell types, namely in the germ line, during early embryogenesis and in post-synaptic sites of nerve cells. This lengthens the poly(A) tail of an mRNA with a shortened poly(A) tail, so that the mRNA will be translated.[44][50] These shortened poly(A) tails are often less than 20 nucleotides, and are lengthened to around 80–150 nucleotides.[3]

In the early mouse embryo, cytoplasmic polyadenylation of maternal RNAs from the egg cell allows the cell to survive and grow even though transcription does not start until the middle of the 2-cell stage (4-cell stage in human).[51][52] In the brain, cytoplasmic polyadenylation is active during learning and could play a role in long-term potentiation, which is the strengthening of the signal transmission from a nerve cell to another in response to nerve impulses and is important for learning and memory formation.[3][53]

Cytoplasmic polyadenylation requires the RNA-binding proteins CPSF and CPEB, and can involve other RNA-binding proteins like Pumilio.[54] Depending on the cell type, the polymerase can be the same type of polyadenylate polymerase (PAP) that is used in the nuclear process, or the cytoplasmic polymerase GLD-2.[55]

 
Results of using different polyadenylation sites on the same gene

Alternative polyadenylation

Many protein-coding genes have more than one polyadenylation site, so a gene can code for several mRNAs that differ in their 3′ end.[27][56][57] The 3’ region of a transcript contains many polyadenylation signals (PAS). When more proximal (closer towards 5’ end) PAS sites are utilized, this shortens the length of the 3’ untranslated region (3' UTR) of a transcript.[58] Studies in both humans and flies have shown tissue specific APA. With neuronal tissues preferring distal PAS usage, leading to longer 3’ UTRs and testis tissues preferring proximal PAS leading to shorter 3’ UTRs.[59][60] Studies have shown there is a correlation between a gene's conservation level and its tendency to do alternative polyadenylation, with highly conserved genes exhibiting more APA. Similarly, highly expressed genes follow this same pattern.[61] Ribo-sequencing data (sequencing of only mRNAs inside ribosomes) has shown that mRNA isoforms with shorter 3’ UTRs are more likely to be translated.[58]

Since alternative polyadenylation changes the length of the 3' UTR,[62] it can also change which binding sites are available for microRNAs in the 3′ UTR.[19][63] MicroRNAs tend to repress translation and promote degradation of the mRNAs they bind to, although there are examples of microRNAs that stabilise transcripts.[64][65] Alternative polyadenylation can also shorten the coding region, thus making the mRNA code for a different protein,[66][67] but this is much less common than just shortening the 3′ untranslated region.[27]

The choice of poly(A) site can be influenced by extracellular stimuli and depends on the expression of the proteins that take part in polyadenylation.[68][69] For example, the expression of CstF-64, a subunit of cleavage stimulatory factor (CstF), increases in macrophages in response to lipopolysaccharides (a group of bacterial compounds that trigger an immune response). This results in the selection of weak poly(A) sites and thus shorter transcripts. This removes regulatory elements in the 3′ untranslated regions of mRNAs for defense-related products like lysozyme and TNF-α. These mRNAs then have longer half-lives and produce more of these proteins.[68] RNA-binding proteins other than those in the polyadenylation machinery can also affect whether a polyadenylation site is used,[70][71][72][73] as can DNA methylation near the polyadenylation signal.[74]

Tagging for degradation in eukaryotes

For many non-coding RNAs, including tRNA, rRNA, snRNA, and snoRNA, polyadenylation is a way of marking the RNA for degradation, at least in yeast.[75] This polyadenylation is done in the nucleus by the TRAMP complex, which maintains a tail that is around 4 nucleotides long to the 3′ end.[76][77] The RNA is then degraded by the exosome.[78] Poly(A) tails have also been found on human rRNA fragments, both the form of homopolymeric (A only) and heterpolymeric (mostly A) tails.[79]

In prokaryotes and organelles

 
Polyadenylation in bacteria helps polynucleotide phosphorylase degrade past secondary structure

In many bacteria, both mRNAs and non-coding RNAs can be polyadenylated. This poly(A) tail promotes degradation by the degradosome, which contains two RNA-degrading enzymes: polynucleotide phosphorylase and RNase E. Polynucleotide phosphorylase binds to the 3′ end of RNAs and the 3′ extension provided by the poly(A) tail allows it to bind to the RNAs whose secondary structure would otherwise block the 3′ end. Successive rounds of polyadenylation and degradation of the 3′ end by polynucleotide phosphorylase allows the degradosome to overcome these secondary structures. The poly(A) tail can also recruit RNases that cut the RNA in two.[80] These bacterial poly(A) tails are about 30 nucleotides long.[81]

In as different groups as animals and trypanosomes, the mitochondria contain both stabilising and destabilising poly(A) tails. Destabilising polyadenylation targets both mRNA and noncoding RNAs. The poly(A) tails are 43 nucleotides long on average. The stabilising ones start at the stop codon, and without them the stop codon (UAA) is not complete as the genome only encodes the U or UA part. Plant mitochondria have only destabilising polyadenylation. Mitochondrial polyadenylation has never been observed in either budding or fission yeast.[82][83]

While many bacteria and mitochondria have polyadenylate polymerases, they also have another type of polyadenylation, performed by polynucleotide phosphorylase itself. This enzyme is found in bacteria,[84] mitochondria,[85] plastids[86] and as a constituent of the archaeal exosome (in those archaea that have an exosome).[87] It can synthesise a 3′ extension where the vast majority of the bases are adenines. Like in bacteria, polyadenylation by polynucleotide phosphorylase promotes degradation of the RNA in plastids[88] and likely also archaea.[82]

Evolution

Although polyadenylation is seen in almost all organisms, it is not universal.[7][89] However, the wide distribution of this modification and the fact that it is present in organisms from all three domains of life implies that the last universal common ancestor of all living organisms, it is presumed, had some form of polyadenylation system.[81] A few organisms do not polyadenylate mRNA, which implies that they have lost their polyadenylation machineries during evolution. Although no examples of eukaryotes that lack polyadenylation are known, mRNAs from the bacterium Mycoplasma gallisepticum and the salt-tolerant archaean Haloferax volcanii lack this modification.[90][91]

The most ancient polyadenylating enzyme is polynucleotide phosphorylase. This enzyme is part of both the bacterial degradosome and the archaeal exosome,[92] two closely related complexes that recycle RNA into nucleotides. This enzyme degrades RNA by attacking the bond between the 3′-most nucleotides with a phosphate, breaking off a diphosphate nucleotide. This reaction is reversible, and so the enzyme can also extend RNA with more nucleotides. The heteropolymeric tail added by polynucleotide phosphorylase is very rich in adenine. The choice of adenine is most likely the result of higher ADP concentrations than other nucleotides as a result of using ATP as an energy currency, making it more likely to be incorporated in this tail in early lifeforms. It has been suggested that the involvement of adenine-rich tails in RNA degradation prompted the later evolution of polyadenylate polymerases (the enzymes that produce poly(A) tails with no other nucleotides in them).[93]

Polyadenylate polymerases are not as ancient. They have separately evolved in both bacteria and eukaryotes from CCA-adding enzyme, which is the enzyme that completes the 3′ ends of tRNAs. Its catalytic domain is homologous to that of other polymerases.[78] It is presumed that the horizontal transfer of bacterial CCA-adding enzyme to eukaryotes allowed the archaeal-like CCA-adding enzyme to switch function to a poly(A) polymerase.[81] Some lineages, like archaea and cyanobacteria, never evolved a polyadenylate polymerase.[93]

Polyadenylate tails are observed in several RNA viruses, including Influenza A,[94] Coronavirus,[95] Alfalfa mosaic virus,[96] and Duck Hepatitis A.[97] Some viruses, such as HIV-1 and Poliovirus, inhibit the cell's poly-A binding protein (PABPC1) in order to emphasize their own genes' expression over the host cell's.[98]

History

Poly(A)polymerase was first identified in 1960 as an enzymatic activity in extracts made from cell nuclei that could polymerise ATP, but not ADP, into polyadenine.[99][100] Although identified in many types of cells, this activity had no known function until 1971, when poly(A) sequences were found in mRNAs.[101][102] The only function of these sequences was thought at first to be protection of the 3′ end of the RNA from nucleases, but later the specific roles of polyadenylation in nuclear export and translation were identified. The polymerases responsible for polyadenylation were first purified and characterized in the 1960s and 1970s, but the large number of accessory proteins that control this process were discovered only in the early 1990s.[101]

See also

References

  1. ^ a b Proudfoot NJ, Furger A, Dye MJ (February 2002). "Integrating mRNA processing with transcription". Cell. 108 (4): 501–12. doi:10.1016/S0092-8674(02)00617-7. PMID 11909521. S2CID 478260.
  2. ^ a b Guhaniyogi J, Brewer G (March 2001). "Regulation of mRNA stability in mammalian cells". Gene. 265 (1–2): 11–23. doi:10.1016/S0378-1119(01)00350-X. PMC 3340483. PMID 11255003.
  3. ^ a b c Richter JD (June 1999). "Cytoplasmic polyadenylation in development and beyond". Microbiology and Molecular Biology Reviews. 63 (2): 446–56. doi:10.1128/MMBR.63.2.446-456.1999. PMC 98972. PMID 10357857.
  4. ^ Steege DA (August 2000). "Emerging features of mRNA decay in bacteria". RNA. 6 (8): 1079–90. doi:10.1017/S1355838200001023. PMC 1369983. PMID 10943888.
  5. ^ Zhuang Y, Zhang H, Lin S (June 2013). "Polyadenylation of 18S rRNA in algae(1)". Journal of Phycology. 49 (3): 570–9. doi:10.1111/jpy.12068. PMID 27007045. S2CID 19863143.
  6. ^ Anderson JT (August 2005). "RNA turnover: unexpected consequences of being tailed". Current Biology. 15 (16): R635-8. doi:10.1016/j.cub.2005.08.002. PMID 16111937. S2CID 19003617.
  7. ^ a b Sarkar N (June 1997). "Polyadenylation of mRNA in prokaryotes". Annual Review of Biochemistry. 66 (1): 173–97. doi:10.1146/annurev.biochem.66.1.173. PMID 9242905.
  8. ^ Stevens A (1963). "Ribonucleic Acids-Biosynthesis and Degradation". Annual Review of Biochemistry. 32: 15–42. doi:10.1146/annurev.bi.32.070163.000311. PMID 14140701.
  9. ^ Lehninger AL, Nelson DL, Cox MM, eds. (1993). Principles of biochemistry (2nd ed.). New York: Worth. ISBN 978-0-87901-500-8.[page needed]
  10. ^ Abaza I, Gebauer F (March 2008). "Trading translation with RNA-binding proteins". RNA. 14 (3): 404–9. doi:10.1261/rna.848208. PMC 2248257. PMID 18212021.
  11. ^ Mattick JS, Makunin IV (April 2006). "Non-coding RNA". Human Molecular Genetics. 15 Spec No 1 (90001): R17-29. doi:10.1093/hmg/ddl046. PMID 16651366.
  12. ^ a b Hunt AG, Xu R, Addepalli B, Rao S, Forbes KP, Meeks LR, Xing D, Mo M, Zhao H, Bandyopadhyay A, Dampanaboina L, Marion A, Von Lanken C, Li QQ (May 2008). "Arabidopsis mRNA polyadenylation machinery: comprehensive analysis of protein-protein interactions and gene expression profiling". BMC Genomics. 9: 220. doi:10.1186/1471-2164-9-220. PMC 2391170. PMID 18479511.
  13. ^ a b Dávila López M, Samuelsson T (January 2008). "Early evolution of histone mRNA 3′ end processing". RNA. 14 (1): 1–10. doi:10.1261/rna.782308. PMC 2151031. PMID 17998288.
  14. ^ Marzluff WF, Gongidi P, Woods KR, Jin J, Maltais LJ (November 2002). "The human and mouse replication-dependent histone genes". Genomics. 80 (5): 487–98. doi:10.1016/S0888-7543(02)96850-3. PMID 12408966.
  15. ^ Saini HK, Griffiths-Jones S, Enright AJ (November 2007). "Genomic analysis of human microRNA transcripts". Proceedings of the National Academy of Sciences of the United States of America. 104 (45): 17719–24. Bibcode:2007PNAS..10417719S. doi:10.1073/pnas.0703890104. PMC 2077053. PMID 17965236.
  16. ^ Yoshikawa M, Peragine A, Park MY, Poethig RS (September 2005). "A pathway for the biogenesis of trans-acting siRNAs in Arabidopsis". Genes & Development. 19 (18): 2164–75. doi:10.1101/gad.1352605. PMC 1221887. PMID 16131612.
  17. ^ Amaral PP, Mattick JS (August 2008). "Noncoding RNA in development". Mammalian Genome. 19 (7–8): 454–92. doi:10.1007/s00335-008-9136-7. PMID 18839252. S2CID 206956408.
  18. ^ a b c d Bienroth S, Keller W, Wahle E (February 1993). "Assembly of a processive messenger RNA polyadenylation complex". The EMBO Journal. 12 (2): 585–94. doi:10.1002/j.1460-2075.1993.tb05690.x. PMC 413241. PMID 8440247.
  19. ^ a b Liu D, Brockman JM, Dass B, Hutchins LN, Singh P, McCarrey JR, MacDonald CC, Graber JH (2006). "Systematic variation in mRNA 3′-processing signals during mouse spermatogenesis". Nucleic Acids Research. 35 (1): 234–46. doi:10.1093/nar/gkl919. PMC 1802579. PMID 17158511.
  20. ^ Lutz CS (October 2008). "Alternative polyadenylation: a twist on mRNA 3′ end formation". ACS Chemical Biology. 3 (10): 609–17. doi:10.1021/cb800138w. PMID 18817380.
  21. ^ a b Beaudoing E, Freier S, Wyatt JR, Claverie JM, Gautheret D (July 2000). "Patterns of variant polyadenylation signal usage in human genes". Genome Research. 10 (7): 1001–10. doi:10.1101/gr.10.7.1001. PMC 310884. PMID 10899149.
  22. ^ Brown KM, Gilmartin GM (December 2003). "A mechanism for the regulation of pre-mRNA 3′ processing by human cleavage factor Im". Molecular Cell. 12 (6): 1467–76. doi:10.1016/S1097-2765(03)00453-2. PMID 14690600.
  23. ^ Yang Q, Gilmartin GM, Doublié S (June 2010). "Structural basis of UGUA recognition by the Nudix protein CFI(m)25 and implications for a regulatory role in mRNA 3′ processing". Proceedings of the National Academy of Sciences of the United States of America. 107 (22): 10062–7. Bibcode:2010PNAS..10710062Y. doi:10.1073/pnas.1000848107. PMC 2890493. PMID 20479262.
  24. ^ Yang Q, Coseno M, Gilmartin GM, Doublié S (March 2011). "Crystal structure of a human cleavage factor CFI(m)25/CFI(m)68/RNA complex provides an insight into poly(A) site recognition and RNA looping". Structure. 19 (3): 368–77. doi:10.1016/j.str.2010.12.021. PMC 3056899. PMID 21295486.
  25. ^ Venkataraman K, Brown KM, Gilmartin GM (June 2005). "Analysis of a noncanonical poly(A) site reveals a tripartite mechanism for vertebrate poly(A) site recognition". Genes & Development. 19 (11): 1315–27. doi:10.1101/gad.1298605. PMC 1142555. PMID 15937220.
  26. ^ a b Millevoi S, Loulergue C, Dettwiler S, Karaa SZ, Keller W, Antoniou M, Vagner S (October 2006). "An interaction between U2AF 65 and CF I(m) links the splicing and 3′ end processing machineries". The EMBO Journal. 25 (20): 4854–64. doi:10.1038/sj.emboj.7601331. PMC 1618107. PMID 17024186.
  27. ^ a b c Shen Y, Ji G, Haas BJ, Wu X, Zheng J, Reese GJ, Li QQ (May 2008). "Genome level analysis of rice mRNA 3′-end processing signals and alternative polyadenylation". Nucleic Acids Research. 36 (9): 3150–61. doi:10.1093/nar/gkn158. PMC 2396415. PMID 18411206.
  28. ^ Glover-Cutter K, Kim S, Espinosa J, Bentley DL (January 2008). "RNA polymerase II pauses and associates with pre-mRNA processing factors at both ends of genes". Nature Structural & Molecular Biology. 15 (1): 71–8. doi:10.1038/nsmb1352. PMC 2836588. PMID 18157150.
  29. ^ Molecular Biology of the Cell, Chapter 6, "From DNA to RNA". 4th edition. Alberts B, Johnson A, Lewis J, et al. New York: Garland Science; 2002.
  30. ^ Stumpf G, Domdey H (November 1996). "Dependence of yeast pre-mRNA 3′-end processing on CFT1: a sequence homolog of the mammalian AAUAAA binding factor". Science. 274 (5292): 1517–20. Bibcode:1996Sci...274.1517S. doi:10.1126/science.274.5292.1517. PMID 8929410. S2CID 34840144.
  31. ^ Iseli C, Stevenson BJ, de Souza SJ, Samaia HB, Camargo AA, Buetow KH, Strausberg RL, Simpson AJ, Bucher P, Jongeneel CV (July 2002). "Long-range heterogeneity at the 3′ ends of human mRNAs". Genome Research. 12 (7): 1068–74. doi:10.1101/gr.62002. PMC 186619. PMID 12097343.
  32. ^ Balbo PB, Bohm A (September 2007). "Mechanism of poly(A) polymerase: structure of the enzyme-MgATP-RNA ternary complex and kinetic analysis". Structure. 15 (9): 1117–31. doi:10.1016/j.str.2007.07.010. PMC 2032019. PMID 17850751.
  33. ^ Viphakone N, Voisinet-Hakil F, Minvielle-Sebastia L (April 2008). "Molecular dissection of mRNA poly(A) tail length control in yeast". Nucleic Acids Research. 36 (7): 2418–33. doi:10.1093/nar/gkn080. PMC 2367721. PMID 18304944.
  34. ^ Wahle E (February 1995). "Poly(A) tail length control is caused by termination of processive synthesis". The Journal of Biological Chemistry. 270 (6): 2800–8. doi:10.1074/jbc.270.6.2800. PMID 7852352.
  35. ^ Dichtl B, Blank D, Sadowski M, Hübner W, Weiser S, Keller W (August 2002). "Yhh1p/Cft1p directly links poly(A) site recognition and RNA polymerase II transcription termination". The EMBO Journal. 21 (15): 4125–35. doi:10.1093/emboj/cdf390. PMC 126137. PMID 12145212.
  36. ^ Nag A, Narsinh K, Martinson HG (July 2007). "The poly(A)-dependent transcriptional pause is mediated by CPSF acting on the body of the polymerase". Nature Structural & Molecular Biology. 14 (7): 662–9. doi:10.1038/nsmb1253. PMID 17572685. S2CID 5777074.
  37. ^ Tefferi A, Wieben ED, Dewald GW, Whiteman DA, Bernard ME, Spelsberg TC (August 2002). "Primer on medical genomics part II: Background principles and methods in molecular genetics". Mayo Clinic Proceedings. 77 (8): 785–808. doi:10.4065/77.8.785. PMID 12173714. S2CID 2237085.
  38. ^ Coller JM, Gray NK, Wickens MP (October 1998). "mRNA stabilization by poly(A) binding protein is independent of poly(A) and requires translation". Genes & Development. 12 (20): 3226–35. doi:10.1101/gad.12.20.3226. PMC 317214. PMID 9784497.
  39. ^ a b Siddiqui N, Mangus DA, Chang TC, Palermino JM, Shyu AB, Gehring K (August 2007). "Poly(A) nuclease interacts with the C-terminal domain of polyadenylate-binding protein domain from poly(A)-binding protein". The Journal of Biological Chemistry. 282 (34): 25067–75. doi:10.1074/jbc.M701256200. PMID 17595167.
  40. ^ Vinciguerra P, Stutz F (June 2004). "mRNA export: an assembly line from genes to nuclear pores". Current Opinion in Cell Biology. 16 (3): 285–92. doi:10.1016/j.ceb.2004.03.013. PMID 15145353.
  41. ^ Gray NK, Coller JM, Dickson KS, Wickens M (September 2000). "Multiple portions of poly(A)-binding protein stimulate translation in vivo". The EMBO Journal. 19 (17): 4723–33. doi:10.1093/emboj/19.17.4723. PMC 302064. PMID 10970864.
  42. ^ Meaux S, Van Hoof A (July 2006). "Yeast transcripts cleaved by an internal ribozyme provide new insight into the role of the cap and poly(A) tail in translation and mRNA decay". RNA. 12 (7): 1323–37. doi:10.1261/rna.46306. PMC 1484436. PMID 16714281.
  43. ^ Kargapolova Y, Levin M, Lackner K, Danckwardt S (June 2017). "sCLIP-an integrated platform to study RNA-protein interactomes in biomedical research: identification of CSTF2tau in alternative processing of small nuclear RNAs". Nucleic Acids Research. 45 (10): 6074–6086. doi:10.1093/nar/gkx152. PMC 5449641. PMID 28334977.
  44. ^ a b Meijer HA, Bushell M, Hill K, Gant TW, Willis AE, Jones P, de Moor CH (2007). "A novel method for poly(A) fractionation reveals a large population of mRNAs with a short poly(A) tail in mammalian cells". Nucleic Acids Research. 35 (19): e132. doi:10.1093/nar/gkm830. PMC 2095794. PMID 17933768.
  45. ^ Lehner B, Sanderson CM (July 2004). "A protein interaction framework for human mRNA degradation". Genome Research. 14 (7): 1315–23. doi:10.1101/gr.2122004. PMC 442147. PMID 15231747.
  46. ^ Wu L, Fan J, Belasco JG (March 2006). "MicroRNAs direct rapid deadenylation of mRNA". Proceedings of the National Academy of Sciences of the United States of America. 103 (11): 4034–9. Bibcode:2006PNAS..103.4034W. doi:10.1073/pnas.0510928103. PMC 1449641. PMID 16495412.
  47. ^ Cui J, Sackton KL, Horner VL, Kumar KE, Wolfner MF (April 2008). "Wispy, the Drosophila homolog of GLD-2, is required during oogenesis and egg activation". Genetics. 178 (4): 2017–29. doi:10.1534/genetics.107.084558. PMC 2323793. PMID 18430932.
  48. ^ Torabi, Seyed-Fakhreddin; Vaidya, Anand T.; Tycowski, Kazimierz T.; DeGregorio, Suzanne J.; Wang, Jimin; Shu, Mei-Di; Steitz, Thomas A.; Steitz, Joan A. (2021-02-05). "RNA stabilization by a poly(A) tail 3′-end binding pocket and other modes of poly(A)-RNA interaction". Science. 371 (6529): eabe6523. doi:10.1126/science.abe6523. ISSN 0036-8075. PMID 33414189. S2CID 231195473.
  49. ^ Wilusz CJ, Wormington M, Peltz SW (April 2001). "The cap-to-tail guide to mRNA turnover". Nature Reviews Molecular Cell Biology. 2 (4): 237–46. doi:10.1038/35067025. PMID 11283721. S2CID 9734550.
  50. ^ Jung MY, Lorenz L, Richter JD (June 2006). "Translational control by neuroguidin, a eukaryotic initiation factor 4E and CPEB binding protein". Molecular and Cellular Biology. 26 (11): 4277–87. doi:10.1128/MCB.02470-05. PMC 1489097. PMID 16705177.
  51. ^ Sakurai T, Sato M, Kimura M (November 2005). "Diverse patterns of poly(A) tail elongation and shortening of murine maternal mRNAs from fully grown oocyte to 2-cell embryo stages". Biochemical and Biophysical Research Communications. 336 (4): 1181–9. doi:10.1016/j.bbrc.2005.08.250. PMID 16169522.
  52. ^ Taft RA (January 2008). "Virtues and limitations of the preimplantation mouse embryo as a model system". Theriogenology. 69 (1): 10–6. doi:10.1016/j.theriogenology.2007.09.032. PMC 2239213. PMID 18023855.
  53. ^ Richter JD (June 2007). "CPEB: a life in translation". Trends in Biochemical Sciences. 32 (6): 279–85. doi:10.1016/j.tibs.2007.04.004. PMID 17481902.
  54. ^ Piqué M, López JM, Foissac S, Guigó R, Méndez R (February 2008). "A combinatorial code for CPE-mediated translational control". Cell. 132 (3): 434–48. doi:10.1016/j.cell.2007.12.038. PMID 18267074. S2CID 16092673.
  55. ^ Benoit P, Papin C, Kwak JE, Wickens M, Simonelig M (June 2008). "PAP- and GLD-2-type poly(A) polymerases are required sequentially in cytoplasmic polyadenylation and oogenesis in Drosophila". Development. 135 (11): 1969–79. doi:10.1242/dev.021444. PMID 18434412.
  56. ^ Tian B, Hu J, Zhang H, Lutz CS (2005). "A large-scale analysis of mRNA polyadenylation of human and mouse genes". Nucleic Acids Research. 33 (1): 201–12. doi:10.1093/nar/gki158. PMC 546146. PMID 15647503.
  57. ^ Danckwardt S, Hentze MW, Kulozik AE (February 2008). "3′ end mRNA processing: molecular mechanisms and implications for health and disease". The EMBO Journal. 27 (3): 482–98. doi:10.1038/sj.emboj.7601932. PMC 2241648. PMID 18256699.
  58. ^ a b Tian, Bin; Manley, James L. (2017). "Alternative polyadenylation of mRNA precursors". Nature Reviews. Molecular Cell Biology. 18 (1): 18–30. doi:10.1038/nrm.2016.116. ISSN 1471-0080. PMC 5483950. PMID 27677860.
  59. ^ Zhang, Haibo; Lee, Ju Youn; Tian, Bin (2005). "Biased alternative polyadenylation in human tissues". Genome Biology. 6 (12): R100. doi:10.1186/gb-2005-6-12-r100. ISSN 1474-760X. PMC 1414089. PMID 16356263.
  60. ^ Smibert, Peter; Miura, Pedro; Westholm, Jakub O.; Shenker, Sol; May, Gemma; Duff, Michael O.; Zhang, Dayu; Eads, Brian D.; Carlson, Joe; Brown, James B.; Eisman, Robert C. (2012). "Global patterns of tissue-specific alternative polyadenylation in Drosophila". Cell Reports. 1 (3): 277–289. doi:10.1016/j.celrep.2012.01.001. ISSN 2211-1247. PMC 3368434. PMID 22685694.
  61. ^ Lee, Ju Youn; Ji, Zhe; Tian, Bin (2008). "Phylogenetic analysis of mRNA polyadenylation sites reveals a role of transposable elements in evolution of the 3'-end of genes". Nucleic Acids Research. 36 (17): 5581–5590. doi:10.1093/nar/gkn540. ISSN 1362-4962. PMC 2553571. PMID 18757892.
  62. ^ Ogorodnikov A, Kargapolova Y, Danckwardt S (June 2016). "Processing and transcriptome expansion at the mRNA 3′ end in health and disease: finding the right end". Pflügers Archiv. 468 (6): 993–1012. doi:10.1007/s00424-016-1828-3. PMC 4893057. PMID 27220521.
  63. ^ Sandberg R, Neilson JR, Sarma A, Sharp PA, Burge CB (June 2008). "Proliferating cells express mRNAs with shortened 3′ untranslated regions and fewer microRNA target sites". Science. 320 (5883): 1643–7. Bibcode:2008Sci...320.1643S. doi:10.1126/science.1155390. PMC 2587246. PMID 18566288.
  64. ^ Tili E, Michaille JJ, Calin GA (April 2008). "Expression and function of micro-RNAs in immune cells during normal or disease state". International Journal of Medical Sciences. 5 (2): 73–9. doi:10.7150/ijms.5.73. PMC 2288788. PMID 18392144.
  65. ^ Ghosh T, Soni K, Scaria V, Halimani M, Bhattacharjee C, Pillai B (November 2008). "MicroRNA-mediated up-regulation of an alternatively polyadenylated variant of the mouse cytoplasmic {beta}-actin gene". Nucleic Acids Research. 36 (19): 6318–32. doi:10.1093/nar/gkn624. PMC 2577349. PMID 18835850.
  66. ^ Alt FW, Bothwell AL, Knapp M, Siden E, Mather E, Koshland M, Baltimore D (June 1980). "Synthesis of secreted and membrane-bound immunoglobulin mu heavy chains is directed by mRNAs that differ at their 3′ ends". Cell. 20 (2): 293–301. doi:10.1016/0092-8674(80)90615-7. PMID 6771018. S2CID 7448467.
  67. ^ Tian B, Pan Z, Lee JY (February 2007). "Widespread mRNA polyadenylation events in introns indicate dynamic interplay between polyadenylation and splicing". Genome Research. 17 (2): 156–65. doi:10.1101/gr.5532707. PMC 1781347. PMID 17210931.
  68. ^ a b Shell SA, Hesse C, Morris SM, Milcarek C (December 2005). "Elevated levels of the 64-kDa cleavage stimulatory factor (CstF-64) in lipopolysaccharide-stimulated macrophages influence gene expression and induce alternative poly(A) site selection". The Journal of Biological Chemistry. 280 (48): 39950–61. doi:10.1074/jbc.M508848200. PMID 16207706.
  69. ^ Ogorodnikov A, Levin M, Tattikota S, Tokalov S, Hoque M, Scherzinger D, Marini F, Poetsch A, Binder H, Macher-Göppinger S, Probst HC, Tian B, Schaefer M, Lackner KJ, Westermann F, Danckwardt S (December 2018). "Transcriptome 3′ end organization by PCF11 links alternative polyadenylation to formation and neuronal differentiation of neuroblastoma". Nature Communications. 9 (1): 5331. Bibcode:2018NatCo...9.5331O. doi:10.1038/s41467-018-07580-5. PMC 6294251. PMID 30552333.
  70. ^ Licatalosi DD, Mele A, Fak JJ, Ule J, Kayikci M, Chi SW, Clark TA, Schweitzer AC, Blume JE, Wang X, Darnell JC, Darnell RB (November 2008). "HITS-CLIP yields genome-wide insights into brain alternative RNA processing". Nature. 456 (7221): 464–9. Bibcode:2008Natur.456..464L. doi:10.1038/nature07488. PMC 2597294. PMID 18978773.
  71. ^ Hall-Pogar T, Liang S, Hague LK, Lutz CS (July 2007). "Specific trans-acting proteins interact with auxiliary RNA polyadenylation elements in the COX-2 3′-UTR". RNA. 13 (7): 1103–15. doi:10.1261/rna.577707. PMC 1894925. PMID 17507659.
  72. ^ Danckwardt S, Kaufmann I, Gentzel M, Foerstner KU, Gantzert AS, Gehring NH, Neu-Yilik G, Bork P, Keller W, Wilm M, Hentze MW, Kulozik AE (June 2007). "Splicing factors stimulate polyadenylation via USEs at non-canonical 3′ end formation signals". The EMBO Journal. 26 (11): 2658–69. doi:10.1038/sj.emboj.7601699. PMC 1888663. PMID 17464285.
  73. ^ Danckwardt S, Gantzert AS, Macher-Goeppinger S, Probst HC, Gentzel M, Wilm M, Gröne HJ, Schirmacher P, Hentze MW, Kulozik AE (February 2011). "p38 MAPK controls prothrombin expression by regulated RNA 3′ end processing". Molecular Cell. 41 (3): 298–310. doi:10.1016/j.molcel.2010.12.032. PMID 21292162.
  74. ^ Wood AJ, Schulz R, Woodfine K, Koltowska K, Beechey CV, Peters J, Bourc'his D, Oakey RJ (May 2008). "Regulation of alternative polyadenylation by genomic imprinting". Genes & Development. 22 (9): 1141–6. doi:10.1101/gad.473408. PMC 2335310. PMID 18451104.
  75. ^ Reinisch KM, Wolin SL (April 2007). "Emerging themes in non-coding RNA quality control". Current Opinion in Structural Biology. 17 (2): 209–14. doi:10.1016/j.sbi.2007.03.012. PMID 17395456.
  76. ^ Jia H, Wang X, Liu F, Guenther UP, Srinivasan S, Anderson JT, Jankowsky E (June 2011). "The RNA helicase Mtr4p modulates polyadenylation in the TRAMP complex". Cell. 145 (6): 890–901. doi:10.1016/j.cell.2011.05.010. PMC 3115544. PMID 21663793.
  77. ^ LaCava J, Houseley J, Saveanu C, Petfalski E, Thompson E, Jacquier A, Tollervey D (June 2005). "RNA degradation by the exosome is promoted by a nuclear polyadenylation complex". Cell. 121 (5): 713–24. doi:10.1016/j.cell.2005.04.029. PMID 15935758. S2CID 14898055.
  78. ^ a b Martin G, Keller W (November 2007). "RNA-specific ribonucleotidyl transferases". RNA. 13 (11): 1834–49. doi:10.1261/rna.652807. PMC 2040100. PMID 17872511.
  79. ^ Slomovic S, Laufer D, Geiger D, Schuster G (2006). "Polyadenylation of ribosomal RNA in human cells". Nucleic Acids Research. 34 (10): 2966–75. doi:10.1093/nar/gkl357. PMC 1474067. PMID 16738135.
  80. ^ Régnier P, Arraiano CM (March 2000). "Degradation of mRNA in bacteria: emergence of ubiquitous features". BioEssays. 22 (3): 235–44. doi:10.1002/(SICI)1521-1878(200003)22:3<235::AID-BIES5>3.0.CO;2-2. PMID 10684583.
  81. ^ a b c Anantharaman V, Koonin EV, Aravind L (April 2002). "Comparative genomics and evolution of proteins involved in RNA metabolism". Nucleic Acids Research. 30 (7): 1427–64. doi:10.1093/nar/30.7.1427. PMC 101826. PMID 11917006.
  82. ^ a b Slomovic S, Portnoy V, Liveanu V, Schuster G (2006). "RNA Polyadenylation in Prokaryotes and Organelles; Different Tails Tell Different Tales". Critical Reviews in Plant Sciences. 25: 65–77. doi:10.1080/07352680500391337. S2CID 86607431.
  83. ^ Chang, Jeong Ho; Tong, Liang (2012). "Mitochondrial poly(A) polymerase and polyadenylation". Biochimica et Biophysica Acta (BBA) - Gene Regulatory Mechanisms. 1819 (9–10): 992–997. doi:10.1016/j.bbagrm.2011.10.012. ISSN 0006-3002. PMC 3307840. PMID 22172994.
  84. ^ Chang SA, Cozad M, Mackie GA, Jones GH (January 2008). "Kinetics of polynucleotide phosphorylase: comparison of enzymes from Streptomyces and Escherichia coli and effects of nucleoside diphosphates". Journal of Bacteriology. 190 (1): 98–106. doi:10.1128/JB.00327-07. PMC 2223728. PMID 17965156.
  85. ^ Nagaike T, Suzuki T, Ueda T (April 2008). "Polyadenylation in mammalian mitochondria: insights from recent studies". Biochimica et Biophysica Acta (BBA) - Gene Regulatory Mechanisms. 1779 (4): 266–9. doi:10.1016/j.bbagrm.2008.02.001. PMID 18312863.
  86. ^ Walter M, Kilian J, Kudla J (December 2002). "PNPase activity determines the efficiency of mRNA 3′-end processing, the degradation of tRNA and the extent of polyadenylation in chloroplasts". The EMBO Journal. 21 (24): 6905–14. doi:10.1093/emboj/cdf686. PMC 139106. PMID 12486011.
  87. ^ Portnoy V, Schuster G (2006). "RNA polyadenylation and degradation in different Archaea; roles of the exosome and RNase R". Nucleic Acids Research. 34 (20): 5923–31. doi:10.1093/nar/gkl763. PMC 1635327. PMID 17065466.
  88. ^ Yehudai-Resheff S, Portnoy V, Yogev S, Adir N, Schuster G (September 2003). "Domain analysis of the chloroplast polynucleotide phosphorylase reveals discrete functions in RNA degradation, polyadenylation, and sequence homology with exosome proteins". The Plant Cell. 15 (9): 2003–19. doi:10.1105/tpc.013326. PMC 181327. PMID 12953107.
  89. ^ Slomovic S, Portnoy V, Schuster G (2008). RNA Turnover in Prokaryotes, Archaea and Organelles: Chapter 24 Detection and Characterization of Polyadenylated RNA in Eukarya, Bacteria, Archaea, and Organelles. Methods in Enzymology. Vol. 447. pp. 501–20. doi:10.1016/S0076-6879(08)02224-6. ISBN 978-0-12-374377-0. PMID 19161858.
  90. ^ Portnoy V, Evguenieva-Hackenberg E, Klein F, Walter P, Lorentzen E, Klug G, Schuster G (December 2005). "RNA polyadenylation in Archaea: not observed in Haloferax while the exosome polynucleotidylates RNA in Sulfolobus". EMBO Reports. 6 (12): 1188–93. doi:10.1038/sj.embor.7400571. PMC 1369208. PMID 16282984.
  91. ^ Portnoy V, Schuster G (June 2008). "Mycoplasma gallisepticum as the first analyzed bacterium in which RNA is not polyadenylated". FEMS Microbiology Letters. 283 (1): 97–103. doi:10.1111/j.1574-6968.2008.01157.x. PMID 18399989.
  92. ^ Evguenieva-Hackenberg E, Roppelt V, Finsterseifer P, Klug G (December 2008). "Rrp4 and Csl4 are needed for efficient degradation but not for polyadenylation of synthetic and natural RNA by the archaeal exosome". Biochemistry. 47 (50): 13158–68. doi:10.1021/bi8012214. PMID 19053279.
  93. ^ a b Slomovic S, Portnoy V, Yehudai-Resheff S, Bronshtein E, Schuster G (April 2008). "Polynucleotide phosphorylase and the archaeal exosome as poly(A)-polymerases". Biochimica et Biophysica Acta (BBA) - Gene Regulatory Mechanisms. 1779 (4): 247–55. doi:10.1016/j.bbagrm.2007.12.004. PMID 18177749.
  94. ^ Poon, Leo L. M.; Pritlove, David C.; Fodor, Ervin; Brownlee, George G. (1 April 1999). "Direct Evidence that the Poly(A) Tail of Influenza A Virus mRNA Is Synthesized by Reiterative Copying of a U Track in the Virion RNA Template". Journal of Virology. 73 (4): 3473–3476. doi:10.1128/JVI.73.4.3473-3476.1999. PMC 104115. PMID 10074205.
  95. ^ Wu, Hung-Yi; Ke, Ting-Yung; Liao, Wei-Yu; Chang, Nai-Yun (2013). "Regulation of Coronaviral Poly(A) Tail Length during Infection". PLOS ONE. 8 (7): e70548. Bibcode:2013PLoSO...870548W. doi:10.1371/journal.pone.0070548. PMC 3726627. PMID 23923003.
  96. ^ Neeleman, Lyda; Olsthoorn, René C. L.; Linthorst, Huub J. M.; Bol, John F. (4 December 2001). "Translation of a nonpolyadenylated viral RNA is enhanced by binding of viral coat protein or polyadenylation of the RNA". Proceedings of the National Academy of Sciences. 98 (25): 14286–14291. Bibcode:2001PNAS...9814286N. doi:10.1073/pnas.251542798. PMC 64674. PMID 11717411.
  97. ^ Chen, Jun-Hao; Zhang, Rui-Hua; Lin, Shao-Li; Li, Peng-Fei; Lan, Jing-Jing; Song, Sha-Sha; Gao, Ji-Ming; Wang, Yu; Xie, Zhi-Jing; Li, Fu-Chang; Jiang, Shi-Jin (2018). "The Functional Role of the 3′ Untranslated Region and Poly(A) Tail of Duck Hepatitis a Virus Type 1 in Viral Replication and Regulation of IRES-Mediated Translation". Frontiers in Microbiology. 9: 2250. doi:10.3389/fmicb.2018.02250. PMC 6167517. PMID 30319572.
  98. ^ "Inhibition of host poly(A)-binding protein by virus ~ ViralZone". viralzone.expasy.org.
  99. ^ Edmonds, Mary; Abrams, Richard (April 1960). "Polynucleotide Biosynthesis: Formation of a Sequence of Adenylate Units from Adenosine Triphosphate by an Enzyme from Thymus Nuclei". Journal of Biological Chemistry. 235 (4): 1142–1149. doi:10.1016/S0021-9258(18)69494-3.
  100. ^ Colgan DF, Manley JL (November 1997). "Mechanism and regulation of mRNA polyadenylation". Genes & Development. 11 (21): 2755–66. doi:10.1101/gad.11.21.2755. PMID 9353246.
  101. ^ a b Edmonds, M (2002). A history of poly A sequences: from formation to factors to function. Progress in Nucleic Acid Research and Molecular Biology. Vol. 71. pp. 285–389. doi:10.1016/S0079-6603(02)71046-5. ISBN 978-0-12-540071-8. PMID 12102557.
  102. ^ Edmonds, M.; Vaughan, M. H.; Nakazato, H. (1 June 1971). "Polyadenylic Acid Sequences in the Heterogeneous Nuclear RNA and Rapidly-Labeled Polyribosomal RNA of HeLa Cells: Possible Evidence for a Precursor Relationship". Proceedings of the National Academy of Sciences. 68 (6): 1336–1340. Bibcode:1971PNAS...68.1336E. doi:10.1073/pnas.68.6.1336. PMC 389184. PMID 5288383.

Further reading

  • Danckwardt S, Hentze MW, Kulozik AE (February 2008). "3′ end mRNA processing: molecular mechanisms and implications for health and disease". The EMBO Journal. 27 (3): 482–98. doi:10.1038/sj.emboj.7601932. PMC 2241648. PMID 18256699.

External links

  •   Media related to Polyadenylation at Wikimedia Commons

January 08, 2023
polyadenylation, addition, poly, tail, transcript, typically, messenger, mrna, poly, tail, consists, multiple, adenosine, monophosphates, other, words, stretch, that, only, adenine, bases, eukaryotes, polyadenylation, part, process, that, produces, mature, mrn. Polyadenylation is the addition of a poly A tail to an RNA transcript typically a messenger RNA mRNA The poly A tail consists of multiple adenosine monophosphates in other words it is a stretch of RNA that has only adenine bases In eukaryotes polyadenylation is part of the process that produces mature mRNA for translation In many bacteria the poly A tail promotes degradation of the mRNA It therefore forms part of the larger process of gene expression Typical structure of a mature eukaryotic mRNA The process of polyadenylation begins as the transcription of a gene terminates The 3 most segment of the newly made pre mRNA is first cleaved off by a set of proteins these proteins then synthesize the poly A tail at the RNA s 3 end In some genes these proteins add a poly A tail at one of several possible sites Therefore polyadenylation can produce more than one transcript from a single gene alternative polyadenylation similar to alternative splicing 1 The poly A tail is important for the nuclear export translation and stability of mRNA The tail is shortened over time and when it is short enough the mRNA is enzymatically degraded 2 However in a few cell types mRNAs with short poly A tails are stored for later activation by re polyadenylation in the cytosol 3 In contrast when polyadenylation occurs in bacteria it promotes RNA degradation 4 This is also sometimes the case for eukaryotic non coding RNAs 5 6 mRNA molecules in both prokaryotes and eukaryotes have polyadenylated 3 ends with the prokaryotic poly A tails generally shorter and fewer mRNA molecules polyadenylated 7 Contents 1 Background on RNA 2 Nuclear polyadenylation 2 1 Function 2 2 Mechanism 2 3 Downstream effects 2 4 Deadenylation 3 Cytoplasmic polyadenylation 4 Alternative polyadenylation 5 Tagging for degradation in eukaryotes 6 In prokaryotes and organelles 7 Evolution 8 History 9 See also 10 References 11 Further reading 12 External linksBackground on RNA EditFurther information RNA and Messenger RNA Chemical structure of RNA The sequence of bases differs between RNA molecules RNAs are a type of large biological molecules whose individual building blocks are called nucleotides The name poly A tail for polyadenylic acid tail 8 reflects the way RNA nucleotides are abbreviated with a letter for the base the nucleotide contains A for adenine C for cytosine G for guanine and U for uracil RNAs are produced transcribed from a DNA template By convention RNA sequences are written in a 5 to 3 direction The 5 end is the part of the RNA molecule that is transcribed first and the 3 end is transcribed last The 3 end is also where the poly A tail is found on polyadenylated RNAs 1 9 Messenger RNA mRNA is RNA that has a coding region that acts as a template for protein synthesis translation The rest of the mRNA the untranslated regions tune how active the mRNA is 10 There are also many RNAs that are not translated called non coding RNAs Like the untranslated regions many of these non coding RNAs have regulatory roles 11 Nuclear polyadenylation EditFunction Edit In nuclear polyadenylation a poly A tail is added to an RNA at the end of transcription On mRNAs the poly A tail protects the mRNA molecule from enzymatic degradation in the cytoplasm and aids in transcription termination export of the mRNA from the nucleus and translation 2 Almost all eukaryotic mRNAs are polyadenylated 12 with the exception of animal replication dependent histone mRNAs 13 These are the only mRNAs in eukaryotes that lack a poly A tail ending instead in a stem loop structure followed by a purine rich sequence termed histone downstream element that directs where the RNA is cut so that the 3 end of the histone mRNA is formed 14 Many eukaryotic non coding RNAs are always polyadenylated at the end of transcription There are small RNAs where the poly A tail is seen only in intermediary forms and not in the mature RNA as the ends are removed during processing the notable ones being microRNAs 15 16 But for many long noncoding RNAs a seemingly large group of regulatory RNAs that for example includes the RNA Xist which mediates X chromosome inactivation a poly A tail is part of the mature RNA 17 Mechanism Edit Proteins involved 12 18 CPSF cleavage polyadenylation specificity factorCstF cleavage stimulation factorPAP polyadenylate polymerasePABII polyadenylate binding protein 2CFI cleavage factor ICFII cleavage factor IIThe processive polyadenylation complex in the nucleus of eukaryotes works on products of RNA polymerase II such as precursor mRNA Here a multi protein complex see components on the right 18 cleaves the 3 most part of a newly produced RNA and polyadenylates the end produced by this cleavage The cleavage is catalysed by the enzyme CPSF 13 18 and occurs 10 30 nucleotides downstream of its binding site 19 This site often has the polyadenylation signal sequence AAUAAA on the RNA but variants of it that bind more weakly to CPSF exist 18 20 Two other proteins add specificity to the binding to an RNA CstF and CFI CstF binds to a GU rich region further downstream of CPSF s site 21 CFI recognises a third site on the RNA a set of UGUAA sequences in mammals 22 23 24 and can recruit CPSF even if the AAUAAA sequence is missing 25 26 The polyadenylation signal the sequence motif recognised by the RNA cleavage complex varies between groups of eukaryotes Most human polyadenylation sites contain the AAUAAA sequence 21 but this sequence is less common in plants and fungi 27 The RNA is typically cleaved before transcription termination as CstF also binds to RNA polymerase II 28 Through a poorly understood mechanism as of 2002 it signals for RNA polymerase II to slip off of the transcript 29 Cleavage also involves the protein CFII though it is unknown how 30 The cleavage site associated with a polyadenylation signal can vary up to some 50 nucleotides 31 When the RNA is cleaved polyadenylation starts catalysed by polyadenylate polymerase Polyadenylate polymerase builds the poly A tail by adding adenosine monophosphate units from adenosine triphosphate to the RNA cleaving off pyrophosphate 32 Another protein PAB2 binds to the new short poly A tail and increases the affinity of polyadenylate polymerase for the RNA When the poly A tail is approximately 250 nucleotides long the enzyme can no longer bind to CPSF and polyadenylation stops thus determining the length of the poly A tail 33 34 CPSF is in contact with RNA polymerase II allowing it to signal the polymerase to terminate transcription 35 36 When RNA polymerase II reaches a termination sequence TTTATT3 on the DNA template and AAUAAA3 on the primary transcript the end of transcription is signaled 37 The polyadenylation machinery is also physically linked to the spliceosome a complex that removes introns from RNAs 26 Downstream effects Edit The poly A tail acts as the binding site for poly A binding protein Poly A binding protein promotes export from the nucleus and translation and inhibits degradation 38 This protein binds to the poly A tail prior to mRNA export from the nucleus and in yeast also recruits poly A nuclease an enzyme that shortens the poly A tail and allows the export of the mRNA Poly A binding protein is exported to the cytoplasm with the RNA mRNAs that are not exported are degraded by the exosome 39 40 Poly A binding protein also can bind to and thus recruit several proteins that affect translation 39 one of these is initiation factor 4G which in turn recruits the 40S ribosomal subunit 41 However a poly A tail is not required for the translation of all mRNAs 42 Further poly A tailing oligo adenylation can determine the fate of RNA molecules that are usually not poly A tailed such as small non coding sn RNAs etc and thereby induce their RNA decay 43 Deadenylation Edit In eukaryotic somatic cells the poly A tails of most mRNAs in the cytoplasm gradually get shorter and mRNAs with shorter poly A tail are translated less and degraded sooner 44 However it can take many hours before an mRNA is degraded 45 This deadenylation and degradation process can be accelerated by microRNAs complementary to the 3 untranslated region of an mRNA 46 In immature egg cells mRNAs with shortened poly A tails are not degraded but are instead stored and translationally inactive These short tailed mRNAs are activated by cytoplasmic polyadenylation after fertilisation during egg activation 47 In animals poly A ribonuclease PARN can bind to the 5 cap and remove nucleotides from the poly A tail The level of access to the 5 cap and poly A tail is important in controlling how soon the mRNA is degraded PARN deadenylates less if the RNA is bound by the initiation factors 4E at the 5 cap and 4G at the poly A tail which is why translation reduces deadenylation The rate of deadenylation may also be regulated by RNA binding proteins Additionally RNA triple helix structures and RNA motifs such as the poly A tail 3 end binding pocket retard deadenylation process and inhibit poly A tail removal 48 Once the poly A tail is removed the decapping complex removes the 5 cap leading to a degradation of the RNA Several other proteins are involved in deadenylation in budding yeast and human cells most notably the CCR4 Not complex 49 Cytoplasmic polyadenylation EditThere is polyadenylation in the cytosol of some animal cell types namely in the germ line during early embryogenesis and in post synaptic sites of nerve cells This lengthens the poly A tail of an mRNA with a shortened poly A tail so that the mRNA will be translated 44 50 These shortened poly A tails are often less than 20 nucleotides and are lengthened to around 80 150 nucleotides 3 In the early mouse embryo cytoplasmic polyadenylation of maternal RNAs from the egg cell allows the cell to survive and grow even though transcription does not start until the middle of the 2 cell stage 4 cell stage in human 51 52 In the brain cytoplasmic polyadenylation is active during learning and could play a role in long term potentiation which is the strengthening of the signal transmission from a nerve cell to another in response to nerve impulses and is important for learning and memory formation 3 53 Cytoplasmic polyadenylation requires the RNA binding proteins CPSF and CPEB and can involve other RNA binding proteins like Pumilio 54 Depending on the cell type the polymerase can be the same type of polyadenylate polymerase PAP that is used in the nuclear process or the cytoplasmic polymerase GLD 2 55 Results of using different polyadenylation sites on the same geneAlternative polyadenylation EditMany protein coding genes have more than one polyadenylation site so a gene can code for several mRNAs that differ in their 3 end 27 56 57 The 3 region of a transcript contains many polyadenylation signals PAS When more proximal closer towards 5 end PAS sites are utilized this shortens the length of the 3 untranslated region 3 UTR of a transcript 58 Studies in both humans and flies have shown tissue specific APA With neuronal tissues preferring distal PAS usage leading to longer 3 UTRs and testis tissues preferring proximal PAS leading to shorter 3 UTRs 59 60 Studies have shown there is a correlation between a gene s conservation level and its tendency to do alternative polyadenylation with highly conserved genes exhibiting more APA Similarly highly expressed genes follow this same pattern 61 Ribo sequencing data sequencing of only mRNAs inside ribosomes has shown that mRNA isoforms with shorter 3 UTRs are more likely to be translated 58 Since alternative polyadenylation changes the length of the 3 UTR 62 it can also change which binding sites are available for microRNAs in the 3 UTR 19 63 MicroRNAs tend to repress translation and promote degradation of the mRNAs they bind to although there are examples of microRNAs that stabilise transcripts 64 65 Alternative polyadenylation can also shorten the coding region thus making the mRNA code for a different protein 66 67 but this is much less common than just shortening the 3 untranslated region 27 The choice of poly A site can be influenced by extracellular stimuli and depends on the expression of the proteins that take part in polyadenylation 68 69 For example the expression of CstF 64 a subunit of cleavage stimulatory factor CstF increases in macrophages in response to lipopolysaccharides a group of bacterial compounds that trigger an immune response This results in the selection of weak poly A sites and thus shorter transcripts This removes regulatory elements in the 3 untranslated regions of mRNAs for defense related products like lysozyme and TNF a These mRNAs then have longer half lives and produce more of these proteins 68 RNA binding proteins other than those in the polyadenylation machinery can also affect whether a polyadenylation site is used 70 71 72 73 as can DNA methylation near the polyadenylation signal 74 Tagging for degradation in eukaryotes EditFor many non coding RNAs including tRNA rRNA snRNA and snoRNA polyadenylation is a way of marking the RNA for degradation at least in yeast 75 This polyadenylation is done in the nucleus by the TRAMP complex which maintains a tail that is around 4 nucleotides long to the 3 end 76 77 The RNA is then degraded by the exosome 78 Poly A tails have also been found on human rRNA fragments both the form of homopolymeric A only and heterpolymeric mostly A tails 79 In prokaryotes and organelles Edit Polyadenylation in bacteria helps polynucleotide phosphorylase degrade past secondary structure In many bacteria both mRNAs and non coding RNAs can be polyadenylated This poly A tail promotes degradation by the degradosome which contains two RNA degrading enzymes polynucleotide phosphorylase and RNase E Polynucleotide phosphorylase binds to the 3 end of RNAs and the 3 extension provided by the poly A tail allows it to bind to the RNAs whose secondary structure would otherwise block the 3 end Successive rounds of polyadenylation and degradation of the 3 end by polynucleotide phosphorylase allows the degradosome to overcome these secondary structures The poly A tail can also recruit RNases that cut the RNA in two 80 These bacterial poly A tails are about 30 nucleotides long 81 In as different groups as animals and trypanosomes the mitochondria contain both stabilising and destabilising poly A tails Destabilising polyadenylation targets both mRNA and noncoding RNAs The poly A tails are 43 nucleotides long on average The stabilising ones start at the stop codon and without them the stop codon UAA is not complete as the genome only encodes the U or UA part Plant mitochondria have only destabilising polyadenylation Mitochondrial polyadenylation has never been observed in either budding or fission yeast 82 83 While many bacteria and mitochondria have polyadenylate polymerases they also have another type of polyadenylation performed by polynucleotide phosphorylase itself This enzyme is found in bacteria 84 mitochondria 85 plastids 86 and as a constituent of the archaeal exosome in those archaea that have an exosome 87 It can synthesise a 3 extension where the vast majority of the bases are adenines Like in bacteria polyadenylation by polynucleotide phosphorylase promotes degradation of the RNA in plastids 88 and likely also archaea 82 Evolution EditAlthough polyadenylation is seen in almost all organisms it is not universal 7 89 However the wide distribution of this modification and the fact that it is present in organisms from all three domains of life implies that the last universal common ancestor of all living organisms it is presumed had some form of polyadenylation system 81 A few organisms do not polyadenylate mRNA which implies that they have lost their polyadenylation machineries during evolution Although no examples of eukaryotes that lack polyadenylation are known mRNAs from the bacterium Mycoplasma gallisepticum and the salt tolerant archaean Haloferax volcanii lack this modification 90 91 The most ancient polyadenylating enzyme is polynucleotide phosphorylase This enzyme is part of both the bacterial degradosome and the archaeal exosome 92 two closely related complexes that recycle RNA into nucleotides This enzyme degrades RNA by attacking the bond between the 3 most nucleotides with a phosphate breaking off a diphosphate nucleotide This reaction is reversible and so the enzyme can also extend RNA with more nucleotides The heteropolymeric tail added by polynucleotide phosphorylase is very rich in adenine The choice of adenine is most likely the result of higher ADP concentrations than other nucleotides as a result of using ATP as an energy currency making it more likely to be incorporated in this tail in early lifeforms It has been suggested that the involvement of adenine rich tails in RNA degradation prompted the later evolution of polyadenylate polymerases the enzymes that produce poly A tails with no other nucleotides in them 93 Polyadenylate polymerases are not as ancient They have separately evolved in both bacteria and eukaryotes from CCA adding enzyme which is the enzyme that completes the 3 ends of tRNAs Its catalytic domain is homologous to that of other polymerases 78 It is presumed that the horizontal transfer of bacterial CCA adding enzyme to eukaryotes allowed the archaeal like CCA adding enzyme to switch function to a poly A polymerase 81 Some lineages like archaea and cyanobacteria never evolved a polyadenylate polymerase 93 Polyadenylate tails are observed in several RNA viruses including Influenza A 94 Coronavirus 95 Alfalfa mosaic virus 96 and Duck Hepatitis A 97 Some viruses such as HIV 1 and Poliovirus inhibit the cell s poly A binding protein PABPC1 in order to emphasize their own genes expression over the host cell s 98 History EditPoly A polymerase was first identified in 1960 as an enzymatic activity in extracts made from cell nuclei that could polymerise ATP but not ADP into polyadenine 99 100 Although identified in many types of cells this activity had no known function until 1971 when poly A sequences were found in mRNAs 101 102 The only function of these sequences was thought at first to be protection of the 3 end of the RNA from nucleases but later the specific roles of polyadenylation in nuclear export and translation were identified The polymerases responsible for polyadenylation were first purified and characterized in the 1960s and 1970s but the large number of accessory proteins that control this process were discovered only in the early 1990s 101 See also EditSimian virus 40 late polyadenylation signal SVLPA References Edit a b Proudfoot NJ Furger A Dye MJ February 2002 Integrating mRNA processing with transcription Cell 108 4 501 12 doi 10 1016 S0092 8674 02 00617 7 PMID 11909521 S2CID 478260 a b Guhaniyogi J Brewer G March 2001 Regulation of mRNA stability in mammalian cells Gene 265 1 2 11 23 doi 10 1016 S0378 1119 01 00350 X PMC 3340483 PMID 11255003 a b c Richter JD June 1999 Cytoplasmic polyadenylation in development and beyond Microbiology and Molecular Biology Reviews 63 2 446 56 doi 10 1128 MMBR 63 2 446 456 1999 PMC 98972 PMID 10357857 Steege DA August 2000 Emerging features of mRNA decay in bacteria RNA 6 8 1079 90 doi 10 1017 S1355838200001023 PMC 1369983 PMID 10943888 Zhuang Y Zhang H Lin S June 2013 Polyadenylation of 18S rRNA in algae 1 Journal of Phycology 49 3 570 9 doi 10 1111 jpy 12068 PMID 27007045 S2CID 19863143 Anderson JT August 2005 RNA turnover unexpected consequences of being tailed Current Biology 15 16 R635 8 doi 10 1016 j cub 2005 08 002 PMID 16111937 S2CID 19003617 a b Sarkar N June 1997 Polyadenylation of mRNA in prokaryotes Annual Review of Biochemistry 66 1 173 97 doi 10 1146 annurev biochem 66 1 173 PMID 9242905 Stevens A 1963 Ribonucleic Acids Biosynthesis and Degradation Annual Review of Biochemistry 32 15 42 doi 10 1146 annurev bi 32 070163 000311 PMID 14140701 Lehninger AL Nelson DL Cox MM eds 1993 Principles of biochemistry 2nd ed New York Worth ISBN 978 0 87901 500 8 page needed Abaza I Gebauer F March 2008 Trading translation with RNA binding proteins RNA 14 3 404 9 doi 10 1261 rna 848208 PMC 2248257 PMID 18212021 Mattick JS Makunin IV April 2006 Non coding RNA Human Molecular Genetics 15 Spec No 1 90001 R17 29 doi 10 1093 hmg ddl046 PMID 16651366 a b Hunt AG Xu R Addepalli B Rao S Forbes KP Meeks LR Xing D Mo M Zhao H Bandyopadhyay A Dampanaboina L Marion A Von Lanken C Li QQ May 2008 Arabidopsis mRNA polyadenylation machinery comprehensive analysis of protein protein interactions and gene expression profiling BMC Genomics 9 220 doi 10 1186 1471 2164 9 220 PMC 2391170 PMID 18479511 a b Davila Lopez M Samuelsson T January 2008 Early evolution of histone mRNA 3 end processing RNA 14 1 1 10 doi 10 1261 rna 782308 PMC 2151031 PMID 17998288 Marzluff WF Gongidi P Woods KR Jin J Maltais LJ November 2002 The human and mouse replication dependent histone genes Genomics 80 5 487 98 doi 10 1016 S0888 7543 02 96850 3 PMID 12408966 Saini HK Griffiths Jones S Enright AJ November 2007 Genomic analysis of human microRNA transcripts Proceedings of the National Academy of Sciences of the United States of America 104 45 17719 24 Bibcode 2007PNAS 10417719S doi 10 1073 pnas 0703890104 PMC 2077053 PMID 17965236 Yoshikawa M Peragine A Park MY Poethig RS September 2005 A pathway for the biogenesis of trans acting siRNAs in Arabidopsis Genes amp Development 19 18 2164 75 doi 10 1101 gad 1352605 PMC 1221887 PMID 16131612 Amaral PP Mattick JS August 2008 Noncoding RNA in development Mammalian Genome 19 7 8 454 92 doi 10 1007 s00335 008 9136 7 PMID 18839252 S2CID 206956408 a b c d Bienroth S Keller W Wahle E February 1993 Assembly of a processive messenger RNA polyadenylation complex The EMBO Journal 12 2 585 94 doi 10 1002 j 1460 2075 1993 tb05690 x PMC 413241 PMID 8440247 a b Liu D Brockman JM Dass B Hutchins LN Singh P McCarrey JR MacDonald CC Graber JH 2006 Systematic variation in mRNA 3 processing signals during mouse spermatogenesis Nucleic Acids Research 35 1 234 46 doi 10 1093 nar gkl919 PMC 1802579 PMID 17158511 Lutz CS October 2008 Alternative polyadenylation a twist on mRNA 3 end formation ACS Chemical Biology 3 10 609 17 doi 10 1021 cb800138w PMID 18817380 a b Beaudoing E Freier S Wyatt JR Claverie JM Gautheret D July 2000 Patterns of variant polyadenylation signal usage in human genes Genome Research 10 7 1001 10 doi 10 1101 gr 10 7 1001 PMC 310884 PMID 10899149 Brown KM Gilmartin GM December 2003 A mechanism for the regulation of pre mRNA 3 processing by human cleavage factor Im Molecular Cell 12 6 1467 76 doi 10 1016 S1097 2765 03 00453 2 PMID 14690600 Yang Q Gilmartin GM Doublie S June 2010 Structural basis of UGUA recognition by the Nudix protein CFI m 25 and implications for a regulatory role in mRNA 3 processing Proceedings of the National Academy of Sciences of the United States of America 107 22 10062 7 Bibcode 2010PNAS 10710062Y doi 10 1073 pnas 1000848107 PMC 2890493 PMID 20479262 Yang Q Coseno M Gilmartin GM Doublie S March 2011 Crystal structure of a human cleavage factor CFI m 25 CFI m 68 RNA complex provides an insight into poly A site recognition and RNA looping Structure 19 3 368 77 doi 10 1016 j str 2010 12 021 PMC 3056899 PMID 21295486 Venkataraman K Brown KM Gilmartin GM June 2005 Analysis of a noncanonical poly A site reveals a tripartite mechanism for vertebrate poly A site recognition Genes amp Development 19 11 1315 27 doi 10 1101 gad 1298605 PMC 1142555 PMID 15937220 a b Millevoi S Loulergue C Dettwiler S Karaa SZ Keller W Antoniou M Vagner S October 2006 An interaction between U2AF 65 and CF I m links the splicing and 3 end processing machineries The EMBO Journal 25 20 4854 64 doi 10 1038 sj emboj 7601331 PMC 1618107 PMID 17024186 a b c Shen Y Ji G Haas BJ Wu X Zheng J Reese GJ Li QQ May 2008 Genome level analysis of rice mRNA 3 end processing signals and alternative polyadenylation Nucleic Acids Research 36 9 3150 61 doi 10 1093 nar gkn158 PMC 2396415 PMID 18411206 Glover Cutter K Kim S Espinosa J Bentley DL January 2008 RNA polymerase II pauses and associates with pre mRNA processing factors at both ends of genes Nature Structural amp Molecular Biology 15 1 71 8 doi 10 1038 nsmb1352 PMC 2836588 PMID 18157150 Molecular Biology of the Cell Chapter 6 From DNA to RNA 4th edition Alberts B Johnson A Lewis J et al New York Garland Science 2002 Stumpf G Domdey H November 1996 Dependence of yeast pre mRNA 3 end processing on CFT1 a sequence homolog of the mammalian AAUAAA binding factor Science 274 5292 1517 20 Bibcode 1996Sci 274 1517S doi 10 1126 science 274 5292 1517 PMID 8929410 S2CID 34840144 Iseli C Stevenson BJ de Souza SJ Samaia HB Camargo AA Buetow KH Strausberg RL Simpson AJ Bucher P Jongeneel CV July 2002 Long range heterogeneity at the 3 ends of human mRNAs Genome Research 12 7 1068 74 doi 10 1101 gr 62002 PMC 186619 PMID 12097343 Balbo PB Bohm A September 2007 Mechanism of poly A polymerase structure of the enzyme MgATP RNA ternary complex and kinetic analysis Structure 15 9 1117 31 doi 10 1016 j str 2007 07 010 PMC 2032019 PMID 17850751 Viphakone N Voisinet Hakil F Minvielle Sebastia L April 2008 Molecular dissection of mRNA poly A tail length control in yeast Nucleic Acids Research 36 7 2418 33 doi 10 1093 nar gkn080 PMC 2367721 PMID 18304944 Wahle E February 1995 Poly A tail length control is caused by termination of processive synthesis The Journal of Biological Chemistry 270 6 2800 8 doi 10 1074 jbc 270 6 2800 PMID 7852352 Dichtl B Blank D Sadowski M Hubner W Weiser S Keller W August 2002 Yhh1p Cft1p directly links poly A site recognition and RNA polymerase II transcription termination The EMBO Journal 21 15 4125 35 doi 10 1093 emboj cdf390 PMC 126137 PMID 12145212 Nag A Narsinh K Martinson HG July 2007 The poly A dependent transcriptional pause is mediated by CPSF acting on the body of the polymerase Nature Structural amp Molecular Biology 14 7 662 9 doi 10 1038 nsmb1253 PMID 17572685 S2CID 5777074 Tefferi A Wieben ED Dewald GW Whiteman DA Bernard ME Spelsberg TC August 2002 Primer on medical genomics part II Background principles and methods in molecular genetics Mayo Clinic Proceedings 77 8 785 808 doi 10 4065 77 8 785 PMID 12173714 S2CID 2237085 Coller JM Gray NK Wickens MP October 1998 mRNA stabilization by poly A binding protein is independent of poly A and requires translation Genes amp Development 12 20 3226 35 doi 10 1101 gad 12 20 3226 PMC 317214 PMID 9784497 a b Siddiqui N Mangus DA Chang TC Palermino JM Shyu AB Gehring K August 2007 Poly A nuclease interacts with the C terminal domain of polyadenylate binding protein domain from poly A binding protein The Journal of Biological Chemistry 282 34 25067 75 doi 10 1074 jbc M701256200 PMID 17595167 Vinciguerra P Stutz F June 2004 mRNA export an assembly line from genes to nuclear pores Current Opinion in Cell Biology 16 3 285 92 doi 10 1016 j ceb 2004 03 013 PMID 15145353 Gray NK Coller JM Dickson KS Wickens M September 2000 Multiple portions of poly A binding protein stimulate translation in vivo The EMBO Journal 19 17 4723 33 doi 10 1093 emboj 19 17 4723 PMC 302064 PMID 10970864 Meaux S Van Hoof A July 2006 Yeast transcripts cleaved by an internal ribozyme provide new insight into the role of the cap and poly A tail in translation and mRNA decay RNA 12 7 1323 37 doi 10 1261 rna 46306 PMC 1484436 PMID 16714281 Kargapolova Y Levin M Lackner K Danckwardt S June 2017 sCLIP an integrated platform to study RNA protein interactomes in biomedical research identification of CSTF2tau in alternative processing of small nuclear RNAs Nucleic Acids Research 45 10 6074 6086 doi 10 1093 nar gkx152 PMC 5449641 PMID 28334977 a b Meijer HA Bushell M Hill K Gant TW Willis AE Jones P de Moor CH 2007 A novel method for poly A fractionation reveals a large population of mRNAs with a short poly A tail in mammalian cells Nucleic Acids Research 35 19 e132 doi 10 1093 nar gkm830 PMC 2095794 PMID 17933768 Lehner B Sanderson CM July 2004 A protein interaction framework for human mRNA degradation Genome Research 14 7 1315 23 doi 10 1101 gr 2122004 PMC 442147 PMID 15231747 Wu L Fan J Belasco JG March 2006 MicroRNAs direct rapid deadenylation of mRNA Proceedings of the National Academy of Sciences of the United States of America 103 11 4034 9 Bibcode 2006PNAS 103 4034W doi 10 1073 pnas 0510928103 PMC 1449641 PMID 16495412 Cui J Sackton KL Horner VL Kumar KE Wolfner MF April 2008 Wispy the Drosophila homolog of GLD 2 is required during oogenesis and egg activation Genetics 178 4 2017 29 doi 10 1534 genetics 107 084558 PMC 2323793 PMID 18430932 Torabi Seyed Fakhreddin Vaidya Anand T Tycowski Kazimierz T DeGregorio Suzanne J Wang Jimin Shu Mei Di Steitz Thomas A Steitz Joan A 2021 02 05 RNA stabilization by a poly A tail 3 end binding pocket and other modes of poly A RNA interaction Science 371 6529 eabe6523 doi 10 1126 science abe6523 ISSN 0036 8075 PMID 33414189 S2CID 231195473 Wilusz CJ Wormington M Peltz SW April 2001 The cap to tail guide to mRNA turnover Nature Reviews Molecular Cell Biology 2 4 237 46 doi 10 1038 35067025 PMID 11283721 S2CID 9734550 Jung MY Lorenz L Richter JD June 2006 Translational control by neuroguidin a eukaryotic initiation factor 4E and CPEB binding protein Molecular and Cellular Biology 26 11 4277 87 doi 10 1128 MCB 02470 05 PMC 1489097 PMID 16705177 Sakurai T Sato M Kimura M November 2005 Diverse patterns of poly A tail elongation and shortening of murine maternal mRNAs from fully grown oocyte to 2 cell embryo stages Biochemical and Biophysical Research Communications 336 4 1181 9 doi 10 1016 j bbrc 2005 08 250 PMID 16169522 Taft RA January 2008 Virtues and limitations of the preimplantation mouse embryo as a model system Theriogenology 69 1 10 6 doi 10 1016 j theriogenology 2007 09 032 PMC 2239213 PMID 18023855 Richter JD June 2007 CPEB a life in translation Trends in Biochemical Sciences 32 6 279 85 doi 10 1016 j tibs 2007 04 004 PMID 17481902 Pique M Lopez JM Foissac S Guigo R Mendez R February 2008 A combinatorial code for CPE mediated translational control Cell 132 3 434 48 doi 10 1016 j cell 2007 12 038 PMID 18267074 S2CID 16092673 Benoit P Papin C Kwak JE Wickens M Simonelig M June 2008 PAP and GLD 2 type poly A polymerases are required sequentially in cytoplasmic polyadenylation and oogenesis in Drosophila Development 135 11 1969 79 doi 10 1242 dev 021444 PMID 18434412 Tian B Hu J Zhang H Lutz CS 2005 A large scale analysis of mRNA polyadenylation of human and mouse genes Nucleic Acids Research 33 1 201 12 doi 10 1093 nar gki158 PMC 546146 PMID 15647503 Danckwardt S Hentze MW Kulozik AE February 2008 3 end mRNA processing molecular mechanisms and implications for health and disease The EMBO Journal 27 3 482 98 doi 10 1038 sj emboj 7601932 PMC 2241648 PMID 18256699 a b Tian Bin Manley James L 2017 Alternative polyadenylation of mRNA precursors Nature Reviews Molecular Cell Biology 18 1 18 30 doi 10 1038 nrm 2016 116 ISSN 1471 0080 PMC 5483950 PMID 27677860 Zhang Haibo Lee Ju Youn Tian Bin 2005 Biased alternative polyadenylation in human tissues Genome Biology 6 12 R100 doi 10 1186 gb 2005 6 12 r100 ISSN 1474 760X PMC 1414089 PMID 16356263 Smibert Peter Miura Pedro Westholm Jakub O Shenker Sol May Gemma Duff Michael O Zhang Dayu Eads Brian D Carlson Joe Brown James B Eisman Robert C 2012 Global patterns of tissue specific alternative polyadenylation in Drosophila Cell Reports 1 3 277 289 doi 10 1016 j celrep 2012 01 001 ISSN 2211 1247 PMC 3368434 PMID 22685694 Lee Ju Youn Ji Zhe Tian Bin 2008 Phylogenetic analysis of mRNA polyadenylation sites reveals a role of transposable elements in evolution of the 3 end of genes Nucleic Acids Research 36 17 5581 5590 doi 10 1093 nar gkn540 ISSN 1362 4962 PMC 2553571 PMID 18757892 Ogorodnikov A Kargapolova Y Danckwardt S June 2016 Processing and transcriptome expansion at the mRNA 3 end in health and disease finding the right end Pflugers Archiv 468 6 993 1012 doi 10 1007 s00424 016 1828 3 PMC 4893057 PMID 27220521 Sandberg R Neilson JR Sarma A Sharp PA Burge CB June 2008 Proliferating cells express mRNAs with shortened 3 untranslated regions and fewer microRNA target sites Science 320 5883 1643 7 Bibcode 2008Sci 320 1643S doi 10 1126 science 1155390 PMC 2587246 PMID 18566288 Tili E Michaille JJ Calin GA April 2008 Expression and function of micro RNAs in immune cells during normal or disease state International Journal of Medical Sciences 5 2 73 9 doi 10 7150 ijms 5 73 PMC 2288788 PMID 18392144 Ghosh T Soni K Scaria V Halimani M Bhattacharjee C Pillai B November 2008 MicroRNA mediated up regulation of an alternatively polyadenylated variant of the mouse cytoplasmic beta actin gene Nucleic Acids Research 36 19 6318 32 doi 10 1093 nar gkn624 PMC 2577349 PMID 18835850 Alt FW Bothwell AL Knapp M Siden E Mather E Koshland M Baltimore D June 1980 Synthesis of secreted and membrane bound immunoglobulin mu heavy chains is directed by mRNAs that differ at their 3 ends Cell 20 2 293 301 doi 10 1016 0092 8674 80 90615 7 PMID 6771018 S2CID 7448467 Tian B Pan Z Lee JY February 2007 Widespread mRNA polyadenylation events in introns indicate dynamic interplay between polyadenylation and splicing Genome Research 17 2 156 65 doi 10 1101 gr 5532707 PMC 1781347 PMID 17210931 a b Shell SA Hesse C Morris SM Milcarek C December 2005 Elevated levels of the 64 kDa cleavage stimulatory factor CstF 64 in lipopolysaccharide stimulated macrophages influence gene expression and induce alternative poly A site selection The Journal of Biological Chemistry 280 48 39950 61 doi 10 1074 jbc M508848200 PMID 16207706 Ogorodnikov A Levin M Tattikota S Tokalov S Hoque M Scherzinger D Marini F Poetsch A Binder H Macher Goppinger S Probst HC Tian B Schaefer M Lackner KJ Westermann F Danckwardt S December 2018 Transcriptome 3 end organization by PCF11 links alternative polyadenylation to formation and neuronal differentiation of neuroblastoma Nature Communications 9 1 5331 Bibcode 2018NatCo 9 5331O doi 10 1038 s41467 018 07580 5 PMC 6294251 PMID 30552333 Licatalosi DD Mele A Fak JJ Ule J Kayikci M Chi SW Clark TA Schweitzer AC Blume JE Wang X Darnell JC Darnell RB November 2008 HITS CLIP yields genome wide insights into brain alternative RNA processing Nature 456 7221 464 9 Bibcode 2008Natur 456 464L doi 10 1038 nature07488 PMC 2597294 PMID 18978773 Hall Pogar T Liang S Hague LK Lutz CS July 2007 Specific trans acting proteins interact with auxiliary RNA polyadenylation elements in the COX 2 3 UTR RNA 13 7 1103 15 doi 10 1261 rna 577707 PMC 1894925 PMID 17507659 Danckwardt S Kaufmann I Gentzel M Foerstner KU Gantzert AS Gehring NH Neu Yilik G Bork P Keller W Wilm M Hentze MW Kulozik AE June 2007 Splicing factors stimulate polyadenylation via USEs at non canonical 3 end formation signals The EMBO Journal 26 11 2658 69 doi 10 1038 sj emboj 7601699 PMC 1888663 PMID 17464285 Danckwardt S Gantzert AS Macher Goeppinger S Probst HC Gentzel M Wilm M Grone HJ Schirmacher P Hentze MW Kulozik AE February 2011 p38 MAPK controls prothrombin expression by regulated RNA 3 end processing Molecular Cell 41 3 298 310 doi 10 1016 j molcel 2010 12 032 PMID 21292162 Wood AJ Schulz R Woodfine K Koltowska K Beechey CV Peters J Bourc his D Oakey RJ May 2008 Regulation of alternative polyadenylation by genomic imprinting Genes amp Development 22 9 1141 6 doi 10 1101 gad 473408 PMC 2335310 PMID 18451104 Reinisch KM Wolin SL April 2007 Emerging themes in non coding RNA quality control Current Opinion in Structural Biology 17 2 209 14 doi 10 1016 j sbi 2007 03 012 PMID 17395456 Jia H Wang X Liu F Guenther UP Srinivasan S Anderson JT Jankowsky E June 2011 The RNA helicase Mtr4p modulates polyadenylation in the TRAMP complex Cell 145 6 890 901 doi 10 1016 j cell 2011 05 010 PMC 3115544 PMID 21663793 LaCava J Houseley J Saveanu C Petfalski E Thompson E Jacquier A Tollervey D June 2005 RNA degradation by the exosome is promoted by a nuclear polyadenylation complex Cell 121 5 713 24 doi 10 1016 j cell 2005 04 029 PMID 15935758 S2CID 14898055 a b Martin G Keller W November 2007 RNA specific ribonucleotidyl transferases RNA 13 11 1834 49 doi 10 1261 rna 652807 PMC 2040100 PMID 17872511 Slomovic S Laufer D Geiger D Schuster G 2006 Polyadenylation of ribosomal RNA in human cells Nucleic Acids Research 34 10 2966 75 doi 10 1093 nar gkl357 PMC 1474067 PMID 16738135 Regnier P Arraiano CM March 2000 Degradation of mRNA in bacteria emergence of ubiquitous features BioEssays 22 3 235 44 doi 10 1002 SICI 1521 1878 200003 22 3 lt 235 AID BIES5 gt 3 0 CO 2 2 PMID 10684583 a b c Anantharaman V Koonin EV Aravind L April 2002 Comparative genomics and evolution of proteins involved in RNA metabolism Nucleic Acids Research 30 7 1427 64 doi 10 1093 nar 30 7 1427 PMC 101826 PMID 11917006 a b Slomovic S Portnoy V Liveanu V Schuster G 2006 RNA Polyadenylation in Prokaryotes and Organelles Different Tails Tell Different Tales Critical Reviews in Plant Sciences 25 65 77 doi 10 1080 07352680500391337 S2CID 86607431 Chang Jeong Ho Tong Liang 2012 Mitochondrial poly A polymerase and polyadenylation Biochimica et Biophysica Acta BBA Gene Regulatory Mechanisms 1819 9 10 992 997 doi 10 1016 j bbagrm 2011 10 012 ISSN 0006 3002 PMC 3307840 PMID 22172994 Chang SA Cozad M Mackie GA Jones GH January 2008 Kinetics of polynucleotide phosphorylase comparison of enzymes from Streptomyces and Escherichia coli and effects of nucleoside diphosphates Journal of Bacteriology 190 1 98 106 doi 10 1128 JB 00327 07 PMC 2223728 PMID 17965156 Nagaike T Suzuki T Ueda T April 2008 Polyadenylation in mammalian mitochondria insights from recent studies Biochimica et Biophysica Acta BBA Gene Regulatory Mechanisms 1779 4 266 9 doi 10 1016 j bbagrm 2008 02 001 PMID 18312863 Walter M Kilian J Kudla J December 2002 PNPase activity determines the efficiency of mRNA 3 end processing the degradation of tRNA and the extent of polyadenylation in chloroplasts The EMBO Journal 21 24 6905 14 doi 10 1093 emboj cdf686 PMC 139106 PMID 12486011 Portnoy V Schuster G 2006 RNA polyadenylation and degradation in different Archaea roles of the exosome and RNase R Nucleic Acids Research 34 20 5923 31 doi 10 1093 nar gkl763 PMC 1635327 PMID 17065466 Yehudai Resheff S Portnoy V Yogev S Adir N Schuster G September 2003 Domain analysis of the chloroplast polynucleotide phosphorylase reveals discrete functions in RNA degradation polyadenylation and sequence homology with exosome proteins The Plant Cell 15 9 2003 19 doi 10 1105 tpc 013326 PMC 181327 PMID 12953107 Slomovic S Portnoy V Schuster G 2008 RNA Turnover in Prokaryotes Archaea and Organelles Chapter 24 Detection and Characterization of Polyadenylated RNA in Eukarya Bacteria Archaea and Organelles Methods in Enzymology Vol 447 pp 501 20 doi 10 1016 S0076 6879 08 02224 6 ISBN 978 0 12 374377 0 PMID 19161858 Portnoy V Evguenieva Hackenberg E Klein F Walter P Lorentzen E Klug G Schuster G December 2005 RNA polyadenylation in Archaea not observed in Haloferax while the exosome polynucleotidylates RNA in Sulfolobus EMBO Reports 6 12 1188 93 doi 10 1038 sj embor 7400571 PMC 1369208 PMID 16282984 Portnoy V Schuster G June 2008 Mycoplasma gallisepticum as the first analyzed bacterium in which RNA is not polyadenylated FEMS Microbiology Letters 283 1 97 103 doi 10 1111 j 1574 6968 2008 01157 x PMID 18399989 Evguenieva Hackenberg E Roppelt V Finsterseifer P Klug G December 2008 Rrp4 and Csl4 are needed for efficient degradation but not for polyadenylation of synthetic and natural RNA by the archaeal exosome Biochemistry 47 50 13158 68 doi 10 1021 bi8012214 PMID 19053279 a b Slomovic S Portnoy V Yehudai Resheff S Bronshtein E Schuster G April 2008 Polynucleotide phosphorylase and the archaeal exosome as poly A polymerases Biochimica et Biophysica Acta BBA Gene Regulatory Mechanisms 1779 4 247 55 doi 10 1016 j bbagrm 2007 12 004 PMID 18177749 Poon Leo L M Pritlove David C Fodor Ervin Brownlee George G 1 April 1999 Direct Evidence that the Poly A Tail of Influenza A Virus mRNA Is Synthesized by Reiterative Copying of a U Track in the Virion RNA Template Journal of Virology 73 4 3473 3476 doi 10 1128 JVI 73 4 3473 3476 1999 PMC 104115 PMID 10074205 Wu Hung Yi Ke Ting Yung Liao Wei Yu Chang Nai Yun 2013 Regulation of Coronaviral Poly A Tail Length during Infection PLOS ONE 8 7 e70548 Bibcode 2013PLoSO 870548W doi 10 1371 journal pone 0070548 PMC 3726627 PMID 23923003 Neeleman Lyda Olsthoorn Rene C L Linthorst Huub J M Bol John F 4 December 2001 Translation of a nonpolyadenylated viral RNA is enhanced by binding of viral coat protein or polyadenylation of the RNA Proceedings of the National Academy of Sciences 98 25 14286 14291 Bibcode 2001PNAS 9814286N doi 10 1073 pnas 251542798 PMC 64674 PMID 11717411 Chen Jun Hao Zhang Rui Hua Lin Shao Li Li Peng Fei Lan Jing Jing Song Sha Sha Gao Ji Ming Wang Yu Xie Zhi Jing Li Fu Chang Jiang Shi Jin 2018 The Functional Role of the 3 Untranslated Region and Poly A Tail of Duck Hepatitis a Virus Type 1 in Viral Replication and Regulation of IRES Mediated Translation Frontiers in Microbiology 9 2250 doi 10 3389 fmicb 2018 02250 PMC 6167517 PMID 30319572 Inhibition of host poly A binding protein by virus ViralZone viralzone expasy org Edmonds Mary Abrams Richard April 1960 Polynucleotide Biosynthesis Formation of a Sequence of Adenylate Units from Adenosine Triphosphate by an Enzyme from Thymus Nuclei Journal of Biological Chemistry 235 4 1142 1149 doi 10 1016 S0021 9258 18 69494 3 Colgan DF Manley JL November 1997 Mechanism and regulation of mRNA polyadenylation Genes amp Development 11 21 2755 66 doi 10 1101 gad 11 21 2755 PMID 9353246 a b Edmonds M 2002 A history of poly A sequences from formation to factors to function Progress in Nucleic Acid Research and Molecular Biology Vol 71 pp 285 389 doi 10 1016 S0079 6603 02 71046 5 ISBN 978 0 12 540071 8 PMID 12102557 Edmonds M Vaughan M H Nakazato H 1 June 1971 Polyadenylic Acid Sequences in the Heterogeneous Nuclear RNA and Rapidly Labeled Polyribosomal RNA of HeLa Cells Possible Evidence for a Precursor Relationship Proceedings of the National Academy of Sciences 68 6 1336 1340 Bibcode 1971PNAS 68 1336E doi 10 1073 pnas 68 6 1336 PMC 389184 PMID 5288383 Further reading EditDanckwardt S Hentze MW Kulozik AE February 2008 3 end mRNA processing molecular mechanisms and implications for health and disease The EMBO Journal 27 3 482 98 doi 10 1038 sj emboj 7601932 PMC 2241648 PMID 18256699 External links Edit Media related to Polyadenylation at Wikimedia Commons Retrieved from https en wikipedia org w index php title Polyadenylation amp oldid 1095739974, wikipedia, wiki, book, books, library,

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