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Poly-A tail

Small nuclear RNAs (snRNAs), a subset of these RNAs, are significantly involved in mRNA processing and gene regulation. Of the several snRNAs, Ul, U2, U4, U5, and U6 are involved in intron removal and the processing of hnRNA into mRNA (Chapter 37). The U7 snRNA may be involved in production of the correct 3 ends of histone mRNA—which lacks a poly(A) tail. The U4 and U6 snRNAs may also be required for poly(A) processing. [Pg.311]

The relationship between hnRNA and the corresponding mature mRNA in eukaryotic cells is now apparent. The hnRNA molecules are the primary transcripts plus their early processed products, which, after the addition of caps and poly(A) tails and removal of the portion corresponding to the introns, are transported to the cytoplasm as mature mRNA molecules. [Pg.354]

As mentioned above, mammahan mRNA molecules contain a 7-methylguanosine cap structure at their 5 terminal, and most have a poly(A) tail at the 3 terminal. The cap stmcmre is added to the 5 end of the newly transcribed mRNA precursor in the nucleus prior to transport of the mELNA molecule to the cytoplasm. The S cap of the RNA transcript is required both for efficient translation initiation and protection of the S end of mRNA from attack by S —> S exonucleases. The secondary methylations of mRNA molecules, those on the 2 -hydroxy and the N of adenylyl residues, occur after the mRNA molecule has appeared in the cytoplasm. [Pg.355]

Poly(A) tails are added to the S end of mRNA molecules in a posttranscriptional processing step. The mRNA is first cleaved about 20 nucleotides downstream from an AAUAA recognition sequence. Another enzyme, poly(A) polymerase, adds a poly(A) tail which is subsequently extended to as many as 200 A residues. The poly(A) tail appears to protect the S end of mRNA from S —> S exonuclease attack. The presence or absence of the poly(A) tail does not determine whether a precursor molecule in the nucleus appears in the cytoplasm, because all poly(A)-tailed hnRNA molecules do not contribute to cytoplasmic mRNA, nor do all cytoplasmic mRNA molecules contain poly(A) tails... [Pg.355]

Biochemical and genetic experiments in yeast have revealed that the b poly(A) tail and its binding protein, Pablp, are required for efficient initiation of protein synthesis. Further studies showed that the poly(A) tail stimulates recruitment of the 40S ribosomal subunit to the mRNA through a complex set of interactions. Pablp, bound to the poly(A) tail, interacts with eIF-4G, which in turn binds to eIF-4E that is bound to the cap structure. It is possible that a circular structure is formed and that this helps direct the 40S ribosomal subunit to the b end of the mRNA. This helps explain how the cap and poly(A) tail structures have a synergistic effect on protein synthesis. It appears that a similar mechanism is at work in mammalian cells. [Pg.365]

Figure 39-19. Structure of a typical eukaryotic mRNA showing elements that are involved in regulating mRNA stability. The typical eukaryotic mRNA has a 5 noncoding sequence (5 NCS), a coding region, and a 3 NCS. All are capped at the 5 end, and most have a polyadenylate sequence at the 3 end. The 5 cap and 3 poly(A) tail protect the mRNA against exonuclease attack. Stem-loop structures in the 5 and 3 NCS, features in the coding sequence, and the AU-rich region in the 3 NCS are thought to play roles in mRNA stability. Figure 39-19. Structure of a typical eukaryotic mRNA showing elements that are involved in regulating mRNA stability. The typical eukaryotic mRNA has a 5 noncoding sequence (5 NCS), a coding region, and a 3 NCS. All are capped at the 5 end, and most have a polyadenylate sequence at the 3 end. The 5 cap and 3 poly(A) tail protect the mRNA against exonuclease attack. Stem-loop structures in the 5 and 3 NCS, features in the coding sequence, and the AU-rich region in the 3 NCS are thought to play roles in mRNA stability.
Figure 1. Expression of c-mos in mouse oocytes, c-mos is transcribed during oocyte growth and transcripts with short poly(A) tails are accumulated in fully-grown germinal vesicle (GV) stage oocytes. These transcripts are polyadenylated and translated following the resumption of meiosis and then degraded following fertilization and cleavage to the two-cell stage. Figure 1. Expression of c-mos in mouse oocytes, c-mos is transcribed during oocyte growth and transcripts with short poly(A) tails are accumulated in fully-grown germinal vesicle (GV) stage oocytes. These transcripts are polyadenylated and translated following the resumption of meiosis and then degraded following fertilization and cleavage to the two-cell stage.
The advantage of mRNA over plasmid transfection is the ability of in vitro transcription to allow precise control over features contained within the mRNA (Humphreys et al., 2005 Pillai et al., 2005 Westman et al, 2005). For example, mRNA can be prepared either with or without the physiological m7G(5/)ppp(5/)G cap structure and S poly(A) tail, which are important mediators of canonical translation initiation (Gallie, 1991 Hentze et al., 2006 Iizuka et al, 1994 Kahvejian et al, 2005 Tarun and Sachs, 1995). [Pg.122]

At this stage, mRNA can be polyadenylated using the poly(A) tailing kit (Ambion), according to the manufacturer s instructions. [Pg.122]

Example experiments using the previous methodologies are shown in Fig. 6.1. The major mRNA constructs described in this chapter are dia-grammatically represented in Fig. 6. IB and an example of in vitro transcribed and polyadenylated R-luc-4 sites mRNA is shown in Fig. 6.1A. In these experiments, translation of R-luc-4 sites mRNA is synergistically promoted by the physiological cap structure and the poly (A) tail (Fig. 6.1C), and full miR-dependent translational repression requires the presence of both modifications (Fig. 6.ID, Humphreys etal., 2005). (TheEMCV IRES-containing constructs are discussed later.)... [Pg.123]

Variations The poly(A) tailing kit (Ambion) produces a mRNA population with varying lengths of poly(A) tails, controlled by altering poly(A) polymerase concentrations and incubation times. An alternate method to incorporate a poly(A) tail is to clone a defined stretch of adenosines/ thymidines into the > UTR of the template pDNA. To allow transcripts to finish on an adenosine, the insert should be followed by a restriction site for an enzyme that cleaves 5 of the last antisense strand thymidine, such as Nsi I. In this way, the poly (A) tail can be incorporated directly into the... [Pg.124]

Bergamini, G., Preiss, T., and Hentze, M. W. (2000). Picomavirus IRESes and the poly(A) tail ioindy promote cap-independent translation in a mammalian cell-free system. RNA 6, 1781-1790. [Pg.144]

Gallie, D. R. (1991). The cap and poly(A) tail function synergistically to regulate mRNA translational efficiency. Genes Dev. 5, 2108—2116. [Pg.144]

Humphreys, D. T., Westman, B. J., Martin, D. I., andPreiss, T. (2005). MicroRNAs control translation initiation by inhibiting eukaryotic initiation factor 4E/cap and poly(A) tail function. Proc. Natl. Acad. Sci. USA 102, 16961-16966. [Pg.144]

Woolstencroft, R. N., Beilharz, T. H., Cook, M. A., Preiss, T., Durocher, D., and Tyers, M. (2006). Ccr4 contributes to tolerance of replication stress through control of CRT1 mRNA poly(A) tail length. J. Cell Sci. 119, 5178-5192. [Pg.146]

The plasmid p/wc-A60 is digested with Ilpal for synthesis of luciferase mRNA with a S -terminal 60-nt poly(A) tail. The RNAs are synthesized in 200-pl reaction mixtures incubated for 2 h at 37° using conditions described previously. Reaction mixtures are further treated with 3 U of DNase RQ1 (Promega) for 20 min at 37°, extracted with phenol and chloroform, and... [Pg.253]

Tarun, S. J. J., and Sachs, A. B. (1996). Association of the yeast poly(A) tail binding protein with translation initiation factor eIF4G. EMBOJ. 15, 7168—7177. [Pg.332]

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See also in sourсe #XX -- [ Pg.260 ]



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