In vitro deadenylation of mammalian mRNA by a HeLa cell 3'' exonuclease.

We have identified a 3' exonuclease in HeLa cell extracts which deadenylates mammalian mRNA and leaves the mRNA body intact after poly(A) removal. Only homopolymeric adenosine tails located at the 3' end were efficiently removed by the exonuclease. The poly(A) removing activity did not require any specific sequences in the mRNA body either for poly(A) removal or for accumulation of the deadenylated mRNA. We conclude that the poly(A) removing activity is a 3' exonuclease since (i) reaction intermediates gradually lose the poly(A) tail, (ii) degradation is prevented by the presence of a cordycepin residue at the 3' end and (iii) RNAs having internally located poly(A) stretches are poor substrates for degradation. The possible involvement of the poly(A) removing enzyme in regulating mRNA translation and stability is discussed.     

A 54-kDa fragment of the Poly(A)-specific ribonuclease is an oligomeric, processive, and cap-interacting Poly(A)-specific 3' exonuclease

We have previously identified a HeLa cell 3' exonuclease specific for degrading poly(A) tails of mRNAs. Here we report on the purification and identification of a calf thymus 54-kDa polypeptide associated with a similar 3' exonuclease activity. The 54-kDa polypeptide was shown to be a fragment of the poly(A)-specific ribonuclease 74-kDa polypeptide. The native molecular mass of the nuclease activity was estimated to be 180-220 kDa. Protein/protein cross-linking revealed an oligomeric structure, most likely consisting of three subunits. The purified nuclease activity released 5'-AMP as the reaction product and degraded poly(A) in a highly processive fashion. The activity required monovalent cations and was dependent on divalent metal ions. The RNA substrate requirement was investigated, and it was found that the nuclease was highly poly(A)-specific and that only 3' end-located poly(A) was degraded by the activity. RNA substrates capped with m(7)G(5')ppp(5')G were more efficiently degraded than noncapped RNA substrates. Addition of free m(7)G(5')ppp(5')G cap analogue inhibited poly(A) degradation in vitro, suggesting a functional link between the RNA 5' end cap structure and poly(A) degradation at the 3' end of the RNA.     

Enhancement of IRES-mediated translation of the c-myc and BiP mRNAs by the poly(A) tail is independent of intact eIF4G and PABP

The poly(A) tail at the 3' end of mRNAs enhances 5' cap-dependent translation initiation. We show that it also enhances IRES-directed translation of two cellular mRNAs in vitro and in vivo. The underlying mechanisms, however, differ fundamentally. In contrast to cap-dependent translation, IRES-driven translation continues to be enhanced by the poly(A) tail following proteolytic cleavage of eIF4G. Moreover, the poly(A) tail stimulates IRES-mediated translation even in the presence of PAIP2 or following effective depletion of the poly(A) binding protein (PABP) from HeLa cell extracts. The PABP-eIF4G bridging complex that is critical for cap-dependent translation is thus dispensable for the enhancement of the IRESs by the poly(A) tail. The polyadenylated mRNA translation from cellular IRESs is also profoundly sensitive to eIF4A activity in vitro. These mechanistic and molecular distinctions implicate the potential for a new layer of translational control mechanisms.     

Characterization of deadenylation in trypanosome extracts and its inhibition by poly(A)-binding protein Pab1p

The stability of mRNAs is an important point in the regulation of gene expression in eukaryotes. The mRNA turnover pathways have been identified in yeast and mammals. However, mRNA turnover pathways in trypanosomes have not been widely studied. Deadenylation is the first step in the major mRNA turnover pathways of yeast and mammals. To better understand mRNA degradation processes in these organisms, we have developed an in vitro mRNA turnover system that is functional for deadenylation. In this system, addition of poly(A) homopolymer activates the deadenylation of poly(A) tails. The trypanosomal deadenylase activity is a 3'-->5' exonuclease specific for adenylate residues, generates 5'-AMP as a product, is magnesium dependent, and is inhibited by neomycin B sulfate. These characteristics suggest similarity with other eukaryotic deadenylases. Furthermore, this activity is cap independent, indicating a potential difference between the trypanosomal activity and PARN, but suggesting similarity to Ccr4p/Pop2p activities. Extracts immunodepleted of Pab1p required the addition of poly(A) competition to activate deadenylation. Trypanosomal Pab1p functions as an inhibitor of the activity under in vitro conditions. Pab1p appears to be one of several mRNA stability proteins in trypanosomal extracts.     

Selective affinity chromatography of DNA polymerases with associated 3' to 5' exonuclease activities

The use of 5'-AMP as a ligand for the affinity chromatography of DNA polymerases with intrinsic 3' to 5' exonuclease activities was investigated. The basis for this is that 5'-AMP would be expected to act as a ligand for the associated 3' to 5' exonuclease. The requirements for binding of Escherichia coli DNA polymerase I, T4 DNA polymerase, and calf thymus DNA polymerase delta, all of which have associated 3' to 5' exonuclease activities, to several commercially available 5'-AMP supports with different linkages of 5'-AMP to either agarose or cellulose were examined. The DNA polymerases which possessed 3' to 5' exonuclease activities were bound to agarose types in which the 5'-phosphoryl group and the 3'-hydroxyl group of the AMP were unsubstituted. Bound enzyme could be eluted by either an increase in ionic strength or competitive binding of nucleoside 5'-monophosphates. Magnesium was found to reinforce the binding of the enzyme to these affinity supports. DNA polymerase alpha, which does not have an associated 3' to 5' exonuclease activity, did not bind to any of these columns. These differences can be used to advantage for the purification of DNA polymerases that have associated 3' to 5' exonuclease activities, as well as a means for establishing the association of 3' to 5' exonuclease activities with DNA polymerases.     

Trypanosoma brucei guide RNA poly(U) tail formation is stabilized by cognate mRNA

Guide RNAs (gRNAs) are small RNAs that provide specificity for uridine addition and deletion during mRNA editing in trypanosomes. Terminal uridylyl transferase (TUTase) adds uridines to pre-mRNAs during RNA editing and adds a poly(U) tail to the 3' end of gRNAs. The poly(U) tail may stabilize the association of gRNAs with cognate mRNA during editing. Both TUTase and gRNAs associate with two ribonucleoprotein complexes, I (19S) and II (35S to 40S). Complex II is believed to be the fully assembled active editing complex, since it contains pre-edited mRNA and enzymes thought necessary for editing. Purification of TUTase from mitochondrial extracts resulted in the identification of two chromatographically distinct TUTase activities. Stable single-uridine addition to different substrate RNAs is performed by the 19S complex, despite the presence of a uridine-specific 3' exonuclease within this complex. Multiple uridines are added to substrate RNAs by a 10S particle that may be an unstable subunit of complex I lacking the uridine-specific 3' exonuclease. Multiple uridines could be stably added onto gRNAs by complex I when the cognate mRNA is present. We propose a model in which the purine-rich region of the cognate mRNA protects the uridine tail from a uridine exonuclease activity that is present within the complex. To test this model, we have mutated the purine-rich region of the pre-mRNA to abolish base-pairing interaction with the poly(U) tail of the gRNA. This RNA fails to protect the uridine tail of the gRNA from exoribonucleolytic trimming and is consistent with a role for the purine-rich region of the mRNA in gRNA maturation.     

A specific polyadenylase from Escherichia coli K12.

A polyadenylase, degrading specifically poly(A) sequences was isolated from Escherichia coli K12. The enzyme was purified about 850 times to practically electrophoretic homogeneity. It was free of poly(A) polymerase activity, as well as of the well known E. coli RNAases I and II. It is stimulated by bivalent cations like Mg2+ and Mn2+ and splits poly(A) to 3'-AMP and therefore it can be considered as an exonuclease. The enzyme does not degrade any other ribohomopolymer or RNA.     

Blocking polyadenylation of mRNA in the chloroplast inhibits its degradation

The addition of poly(A)-rich sequences to endonuclease cleavage products of chloroplast mRNA has recently been suggested to target the polyadenylated RNA for rapid exonucleolytic degradation. This study analyzed whether the addition of a poly(A)-rich tail to RNA molecules is required for degradation by chloroplast exonuclease(s). In lyzed chloroplasts from spinach, addition of the polyadenylation inhibitor, cordycepin triphosphate (3′-dATP), inhibited the degradation of psbA and rbcL mRNAs. Furthermore, degradation intermediates generated by endonucleolytic cleavages accumulated. Similar results were obtained when yeast tRNA was added to the mRNA degradation system as a non-specific exoribonuclease inhibitor. Nevertheless, the stabilization mechanisms differ: while tRNA directly affects the exonuclease activity, 3′dATP has an indirect effect by inhibiting polyadenylation. The results indicate that the addition of poly(A)-rich sequences to endonucleolytic cleavage products of chloroplast mRNA is required to target these RNAs for rapid exonucleolytic degradation. Together with previous work, the data reported here support a model for mRNA degradation in the chloroplast in which endonucleolytic cleavages are followed by the addition of poly(A)-rich sequences to the proximal cleavage products, targeting these RNAs for rapid exonucleolytic decay.     

Cap-dependent deadenylation of mRNA

Poly(A) tail removal is often the initial and rate-limiting step in mRNA decay and is also responsible for translational silencing of maternal mRNAs during oocyte maturation and early development. Here we report that deadenylation in HeLa cell extracts and by a purified mammalian poly(A)-specific exoribonuclease, PARN (previously designated deadenylating nuclease, DAN), is stimulated by the presence of an m(7)-guanosine cap on substrate RNAs. Known cap-binding proteins, such as eIF4E and the nuclear cap-binding complex, are not detectable in the enzyme preparation, and PARN itself binds to m(7)GTP-Sepharose and is eluted specifically with the cap analog m(7)GTP. Xenopus PARN is known to catalyze mRNA deadenylation during oocyte maturation. The enzyme is depleted from oocyte extract with m(7)GTP-Sepharose, can be photocross-linked to the m(7)GpppG cap and deadenylates m(7)GpppG-capped RNAs more efficiently than ApppG-capped RNAs both in vitro and in vivo. These data provide additional evidence that PARN is responsible for deadenylation during oocyte maturation and suggest that interactions between 5' cap and 3' poly(A) tail may integrate translational efficiency with mRNA stability.     

Yeast Pab1 interacts with Rna15 and participates in the control of the poly(A) tail length in vitro.

In Saccharomyces cerevisiae, the single poly(A) binding protein, Pab1, is the major ribonucleoprotein associated with the poly(A) tails of mRNAs in both the nucleus and the cytoplasm. We found that Pab1 interacts with Rna15 in two-hybrid assays and in coimmunoprecipitation experiments. Overexpression of PAB1 partially but specifically suppressed the rna15-2 mutation in vivo. RNA15 codes for a component of the cleavage and polyadenylation factor CF I, one of the four factors needed for pre-mRNA 3'-end processing. We show that Pab1 and CF I copurify in anion-exchange chromatography. These data suggest that Pab1 is physically associated with CF I. Extracts from a thermosensitive pab1 mutant and from a wild-type strain immunoneutralized for Pab1 showed normal cleavage activity but a large increase in poly(A) tail length. A normal tail length was restored by adding recombinant Pab1 to the mutant extract. The longer poly(A) tails were not due to an inhibition of exonuclease activities. Pab1 has previously been implicated in the regulation of translation initiation and in cytoplasmic mRNA stability. Our data indicate that Pab1 is also a part of the 3'-end RNA-processing complex and thus participates in the control of the poly(A) tail lengths during the polyadenylation reaction.     

Kinetic proofreading scanning models for eukaryotic translational initiation: the cap and poly(A) tail dependency of translation

Two simplified kinetic proofreading scanning (KPS) models were proposed to describe the 5' cap and 3' poly(A) tail dependency of eukaryotic translation initiation. In Model I, the initiation factor complex starts scanning and unwinding the secondary structure of the 5' untranslated region (UTR) from the 5' terminus of mRNA. In Model II, the initiation factor complex starts scanning from any binding site in the 5' UTR. In both models, following ATP hydrolysis, the initiation factor complex either dissociates from mRNA or continues to scan and unwind RNA secondary structure in the 5' UTR. This step repeats n times until the AUG codon is reached. These two models show very different cap and/or poly(A) tail dependency of translation initiation. The models predict that both cap and poly(A) tail dependencies of translation, and translatability of mRNAs are coupled with the structure of 5' UTR: the translation of mRNA with structured 5' UTR is strongly cap- and poly(A) tail-dependent; while translation of mRNA with unstructured 5' UTR is less cap- and poly(A) tail-dependent. We use these two models to explain: (1) the cap and poly(A) tail dependence of translation; (2) the effect of exogenous poly(A) on translation; (3) repression of host mRNA and translation of late adenovirus mRNA in the late phase of adenovirus infection; (4) repression of host mRNA and translation of Vaccinia virus mRNA in virus-infected cell; (5) heat shock repression of translation of normal mRNA and stimulation of translation of hsp mRNA; and (6) the synergistic effect of cap and poly(A) tail on stimulating translation. The kinetic proofreading scanning models provide a coherent interpretation of those phenomena.     

A complex containing the CCR4 and CAF1 proteins is involved in mRNA deadenylation in Drosophila

The CCR4-NOT complex is the major enzyme catalyzing mRNA deadenylation in Saccharomyces cerevisiae. We have identified homologs for almost all subunits of this complex in the Drosophila genome. Biochemical fractionation showed that the two likely catalytic subunits, CCR4 and CAF1, were associated with each other and with a poly(A)-specific 3' exonuclease activity. In Drosophila, the CCR4 and CAF1 proteins were ubiquitously expressed and present in cytoplasmic foci. Individual knock-down of several potential subunits of the Drosophila CCR4-NOT complex by RNAi in tissue culture cells led to a lengthening of bulk mRNA poly(A) tails. Knock-down of two individual subunits also interfered with the rapid deadenylation of Hsp70 mRNA during recovery from heat shock. Similarly, ccr4 mutant flies had elongated bulk poly(A) and a defect in Hsp70 mRNA deadenylation. A minor increase in bulk poly(A) tail length was also observed in Rga mutant flies, which are affected in the NOT2 subunit. The data show that the CCR4-NOT complex is conserved in Drosophila melanogaster and plays a role in general and regulated mRNA deadenylation.     

Cap-Poly(A) synergy in mammalian cell-free extracts. Investigation of the requirements for poly(A)-mediated stimulation of translation initiation

The 5' cap and 3' poly(A) tail of eukaryotic mRNAs cooperate to stimulate synergistically translation initiation in vivo, a phenomenon observed to date in vitro only in translation systems containing endogenous competitor mRNAs. Here we describe nuclease-treated rabbit reticulocyte lysates and HeLa cell cytoplasmic extracts that reproduce cap-poly(A) synergy in the absence of such competitor RNAs. Extracts were rendered poly(A)-dependent by ultracentrifugation to partially deplete them of ribosomes and associated initiation factors. Under optimal conditions, values for synergy in reticulocyte lysates approached 10-fold. By using this system, we investigated the molecular mechanism of poly(A) stimulation of translation. Maximal cap-poly(A) cooperativity required the integrity of the eukaryotic initiation factor 4G-poly(A)-binding protein (eIF4G-PABP) interaction, suggesting that synergy results from mRNA circularization. In addition, polyadenylation stimulated uncapped cellular mRNA translation and that driven by the encephalomyocarditis virus internal ribosome entry segment (IRES). These effects of poly(A) were also sensitive to disruption of the eIF4G-PABP interaction, suggesting that 5'-3' end cross-talk is functionally conserved between classical mRNAs and an IRES-containing mRNA. Finally, we demonstrate that a rotaviral non-structural protein that evicts PABP from eIF4G is capable of provoking the shut-off of host cell translation seen during rotavirus infection.     

Messenger RNA turnover in eukaryotes: pathways and enzymes

The control of mRNA degradation is an important component of the regulation of gene expression since the steady-state concentration of mRNA is determined both by the rates of synthesis and of decay. Two general pathways of mRNA decay have been described in eukaryotes. Both pathways share the exonucleolytic removal of the poly(A) tail (deadenylation) as the first step. In one pathway, deadenylation is followed by the hydrolysis of the cap and processive degradation of the mRNA body by a 5' exonuclease. In the second pathway, the mRNA body is degraded by a complex of 3' exonucleases before the remaining cap structure is hydrolyzed. This review discusses the proteins involved in the catalysis and control of both decay pathways.     

Messenger RNA Turnover in Eukaryotes: Pathways and Enzymes

The control of mRNA degradation is an important component of the regulation of gene expression since the steady-state concentration of mRNA is determined both by the rates of synthesis and of decay. Two general pathways of mRNA decay have been described in eukaryotes. Both pathways share the exonucleolytic removal of the poly(A) tail (deadenylation) as the first step. In one pathway, deadenylation is followed by the hydrolysis of the cap and processive degradation of the mRNA body by a 5′ exonuclease. In the second pathway, the mRNA body is degraded by a complex of 3′ exonucleases before the remaining cap structure is hydrolyzed. This review discusses the proteins involved in the catalysis and control of both decay pathways.