Role of poly(A) polymerase in the cleavage and polyadenylation of mRNA precursor

Structures of mammalian GLD-2 proteins reveal molecular basis of their functional diversity in mRNA and microRNA processing

The stability and processing of cellular RNA transcripts are efficiently controlled via non-templated addition of single or multiple nucleotides, which is catalyzed by various nucleotidyltransferases including poly(A) polymerases (PAPs). Germline development defective 2 (GLD-2) is among the first reported cytoplasmic non-canonical PAPs that promotes the translation of germline-specific mRNAs by extending their short poly(A) tails in metazoan, such as Caenorhabditis elegans and Xenopus. On the other hand, the function of mammalian GLD-2 seems more diverse, which includes monoadenylation of certain microRNAs. To understand the structural basis that underlies the difference between mammalian and non-mammalian GLD-2 proteins, we determine crystal structures of two rodent GLD-2s. Different from C. elegans GLD-2, mammalian GLD-2 is an intrinsically robust PAP with an extensively positively charged surface. Rodent and C. elegans GLD-2s have a topological difference in the β-sheet region of the central domain. Whereas C. elegans GLD-2 prefers adenosine-rich RNA substrates, mammalian GLD-2 can work on RNA oligos with various sequences. Coincident with its activity on microRNAs, mammalian GLD-2 structurally resembles the mRNA and miRNA processor terminal uridylyltransferase 7 (TUT7). Our study reveals how GLD-2 structurally evolves to a more versatile nucleotidyltransferase, and provides important clues in understanding its biological function in mammals.

Polyadenylation of SV40 late pre-mRNA is dependent on phosphorylation of an essential component associated with the 3' end processing machinery

We investigated whether phosphorylation of the essential components involved in the 3' end processing of mRNAs was required for mRNA polyadenylation. The proteins in HeLa nuclear extract were dephosphorylated with alkaline phosphatase, which is known to remove the phosphate moieties from serine and tyrosine. The dephosphorylated extract was used for analyzing cleavage-dependent polyadenylation of SV40 late pre-mRNA. The phosphatase treatment of the extract completely blocked the polyadenylation reaction, whereas dephosphorylation of the extract did not inhibit the cleavage reaction. Since the cleavage depends upon functional integrity of the specificity factor, it is unlikely that the phosphorylated state of the latter factor is required for the 3' end processing. Sodium vanadate, a potent inhibitor of alkaline phosphatase, markedly reduced the inhibitory effect of the phosphatase on the polyadenylation reaction. Dephosphorylation of the extract also prevented formation of the polyadenylation-specific complex with pre-mRNA, whereas the cleavage-specific complexes were formed under this condition. The Mn-dependent polyadenylation, which is largely poly(A) extension reaction, was relatively resistant to the phosphatase treatment. These data indicate that phosphorylation of a key factor is essential for the 3' end processing of pre-mRNA, and suggest that the factor may be poly(A) polymerase.

Nucleases of the metallo-beta-lactamase family and their role in DNA and RNA metabolism

Proteins of the metallo-beta-lactamase family with either demonstrated or predicted nuclease activity have been identified in a number of organisms ranging from bacteria to humans and has been shown to be important constituents of cellular metabolism. Nucleases of this family are believed to utilize a zinc-dependent mechanism in catalysis and function as 5' to 3' exonucleases and or endonucleases in such processes as 3' end processing of RNA precursors, DNA repair, V(D)J recombination, and telomere maintenance. Examples of metallo-beta-lactamase nucleases include CPSF-73, a known component of the cleavage/polyadenylation machinery, which functions as the endonuclease in 3' end formation of both polyadenylated and histone mRNAs, and Artemis that opens DNA hairpins during V(D)J recombination. Mutations in two metallo-beta-lactamase nucleases have been implicated in human diseases: tRNase Z required for 3' processing of tRNA precursors has been linked to the familial form of prostate cancer, whereas inactivation of Artemis causes severe combined immunodeficiency (SCID). There is also a group of as yet uncharacterized proteins of this family in bacteria and archaea that based on sequence similarity to CPSF-73 are predicted to function as nucleases in RNA metabolism. This article reviews the cellular roles of nucleases of the metallo-beta-lactamase family and the recent advances in studying these proteins.

Formation of the 3' end of histone mRNA: getting closer to the end

Nearly all eukaryotic mRNAs end with a poly(A) tail that is added to their 3' end by the ubiquitous cleavage/polyadenylation machinery. The only known exceptions to this rule are metazoan replication-dependent histone mRNAs, which end with a highly conserved stem-loop structure. This distinct 3' end is generated by specialized 3' end processing machinery that cleaves histone pre-mRNAs 4-5 nucleotides downstream of the stem-loop and consists of the U7 small nuclear RNP (snRNP) and number of protein factors. Recently, the U7 snRNP has been shown to contain a unique Sm core that differs from that of the spliceosomal snRNPs, and an essential heat labile processing factor has been identified as symplekin. In addition, cross-linking studies have pinpointed CPSF-73 as the endonuclease, which catalyzes the cleavage reaction. Thus, many of the critical components of the 3' end processing machinery are now identified. Strikingly, this machinery is not as unique as initially thought but contains at least two factors involved in cleavage/polyadenylation, suggesting that the two mechanisms have a common evolutionary origin. The greatest challenge that lies ahead is to determine how all these factors interact with each other to form a catalytically competent processing complex capable of cleaving histone pre-mRNAs.

X-ray crystallographic and steady state fluorescence characterization of the protein dynamics of yeast polyadenylate polymerase

Polyadenylate polymerase (PAP) catalyzes the synthesis of poly(A) tails on the 3'-end of pre-mRNA. PAP is composed of three domains: an N-terminal nucleotide-binding domain (homologous to the palm domain of DNA and RNA polymerases), a middle domain (containing other conserved, catalytically important residues), and a unique C-terminal domain (involved in protein-protein interactions required for 3'-end formation). Previous X-ray crystallographic studies have shown that the domains are arranged in a V-shape such that they form a central cleft with the active site located at the base of the cleft at the interface between the N-terminal and middle domains. In the previous studies, the nucleotides were bound directly to the N-terminal domain and exhibited a conspicuous lack of adenine-specific interactions that would constitute nucleotide recognition. Furthermore, it was postulated that base-specific contacts with residues in the middle domain could occur either as a result of a change in the conformation of the nucleotide or domain movement. To address these issues and to better characterize the structural basis of substrate recognition and catalysis, we report two new crystal structures of yeast PAP. A comparison of these structures reveals that the N-terminal and C-terminal domains of PAP move independently as rigid bodies along two well defined axes of rotation. Modeling of the nucleotide into the most closed state allows us to deduce specific nucleotide interactions involving residues in the middle domain (K215, Y224 and N226) that are proposed to be involved in substrate binding and specificity. To further investigate the nature of PAP domain flexibility, 2-aminopurine labeled molecular probes were employed in steady state fluorescence and acrylamide quenching experiments. The results suggest that the closed domain conformation is stabilized upon recognition of the correct subtrate, MgATP, in an enzyme-substrate ternary complex. The implications of these results on the enzyme mechanism of PAP and the possible role for domain motion in an induced fit mechanism are discussed.

Dinucleoside polyphosphates stimulate the primer independent synthesis of poly(A) catalyzed by yeast poly(A) polymerase

Novel properties of the primer independent synthesis of poly(A), catalyzed by the yeast poly(A) polymerase are presented. The commercial enzyme from yeast, in contrast to the enzyme from Escherichia coli, is unable to adenylate the 3'-OH end of nucleosides, nucleotides or dinucleoside polyphosphates (NpnN). In the presence of 0.05 mm ATP, dinucleotides (at 0.01 mm) activated the enzyme velocity in the following decreasing order: Gp4G, 100; Gp3G, 82; Ap6A, 61; Gp2G, 52; Ap4A, 51; Ap2A, 41; Gp5G, 36; Ap5A, 27; Ap3A, 20, where 100 represents a 10-fold activation in relation to a control without effector. The velocity of the enzyme towards its substrate ATP displayed sigmoidal kinetics with a Hill coefficient (nH) of 1.6 and a Km(S0.5) value of 0.308 +/- 0.120 mm. Dinucleoside polyphosphates did not affect the maximum velocity (Vmax) of the reaction, but did alter its nH and Km(S0.5) values. In the presence of 0.01 mm Gp4G or Ap4A the nH and Km(S0.5) values were (1.0 and 0.063 +/- 0.012 mm) and (0.8 and 0.170 +/- 0.025 mm), respectively. With these kinetic properties, a dinucleoside polyphosphate concentration as low as 1 micro m may have a noticeable activating effect on the synthesis of poly(A) by the enzyme. These findings together with previous publications from this laboratory point to a potential relationship between dinucleoside polyphosphates and enzymes catalyzing the synthesis and/or modification of DNA or RNA.

Poly(A) polymerase from Escherichia coli adenylylates the 3'-hydroxyl residue of nucleosides, nucleoside 5'-phosphates and nucleoside(5')oligophospho(5')nucleosides (NpnN)

The capacity of Escherichia coli poly(A) polymerase to adenylylate the 3'-OH residue of a variety of nucleosides, nucleoside 5'-phosphates and dinucleotides of the type nucleoside(5')oligophospho(5')nucleoside is described here for the first time. Using micromolar concentrations of [alpha-32P]ATP, the following nucleosides/nucleotides were found to be substrates of the reaction: guanosine, AMP, CMP, GMP, IMP, GDP, CTP, dGTP, GTP, XTP, adenosine(5')diphospho(5')adenosine (Ap2A), adenosine (5')triphospho(5')adenosine (Ap3A), adenosine(5')tetraphospho(5')adenosine (Ap4A), adenosine(5')pentaphospho(5')adenosine (Ap5A), guanosine(5')diphospho(5') guanosine (Gp2G), guanosine(5')triphospho(5')guanosine (Gp3G), guanosine(5')tetraphospho(5')guanosine (Gp4G), and guanosine(5')pentaphospho(5')guanosine (Gp5G). The synthesized products were analysed by TLC or HPLC and characterized by their UV spectra, and by treatment with alkaline phosphatase and snake venom phosphodiesterase. The presence of 1 mM GMP inhibited competitively the polyadenylylation of tRNA. We hypothesize that the type of methods used to measure polyadenylation of RNA is the reason why this novel property of E. coli poly(A) polymerase has not been observed previously.

Eukaryotic gene expression: metabolite control by amino acids

Our understanding of the metabolite control in mammalian cells lags far behind that in prokaryotes. This is particularly true for amino-acid-dependent gene expression. Few proteins have been identified for which synthesis is selectively regulated by amino-acid availability, and the mechanisms for control of transcription and translation in response to changes in amino-acid availability have not yet been elucidated. The intimate relationship between amino-acid supply and the fundamental cellular process of protein synthesis makes amino-acid-dependent control of gene expression particularly important. Future studies should provide important insight into amino-acid and other nutrient signaling pathways, and their impact on cellular growth and metabolism.

Sequence of the gamma 2b membrane 3' untranslated region: polya site determination and comparison to the gamma 2a membrane 3' untranslated region

We present here the nucleotide sequence of the gamma 2b membrane 3' untranslated region as well as approximately 443 nucleotides of 3' flanking sequence. Although this region contains two potential polyadenylation hexanucleotides AATAAA (located 1328 and 1407 nucleotides downstream of the last membrane exon), it appears that only the first site directs polyadenylation of the mature mRNA. The first AATAAA is followed by several sequences which may influence its relative strength: the region downstream of this AATAAA is 44% T-rich and contains a pair of CAYTG sequences (4/5 match) which overlap two sequences which have a 6/8 match to the sequence YGTGTTYY. These sequences have been found in proximity to a large number of 3' ends [Gil and Proudfoot, Cell 49, 399-406 (1987); McLauchlan et al., Nucl. Acids Res. 13, 1347-1368. (1985); Berget, Nature 309, 179-182 (1984)]. The AATAAA site at position 1407 is not flanked by a T- or GT-rich sequence and is followed by a single CAYTG sequence (4/5 match) and a single YGTGTTYY sequence (6/8 match). The region downstream of the second AATAAA site also contains a sequence which has an 8/12 match with a sequence found in all heavy chain secreted 3' untranslated regions [Kobrin et al., Molec. Cell. Biol. 6, 1687-1697 (1986)]. Consistent with sequence comparisons between other regions of these two genes, the gamma 2b sequence has striking homology with the gamma 2a 3' untranslated region. A notable difference between gamma 2b and gamma 2a is the absence of an extensive array of GAA, GA, GGAA, and GGA repeats from the gamma 2b sequence. The GA repeats are postulated to form a stem loop structure in the gamma 2a 3' untranslated region; gamma 2b then would be missing the 5' half of the stem. Interestingly, neither the gamma 2b nor the gamma 2a 3' untranslated regions show large homologies to the mu, delta, gamma 3, or the alpha membrane 3' untranslated regions.

A simple procedure for isolation of eukaryotic mRNA polyadenylation factors

We have devised a simple chromatographic procedure which isolates five polyadenylation factors that are required for polyadenylation of eukaryotic mRNA. The factors were separated from each other by fractionation of HeLa cell nuclear extract in two consecutive chromatographic steps. RNA cleavage at the L3 polyadenylation site of human adenovirus 2 required at least four factors. Addition of adenosine residues required only two of these factors. The fractionation procedure separates two components that are both likely to be poly(A) polymerases. The candidate poly(A) polymerases were interchangeable and participated during both RNA cleavage and adenosine addition. They were discriminated from each other by chromatographic properties, heat sensitivity and divalent cation requirement. We have compared our data with published information and have been able to correlate the activities that we have isolated to previously identified polyadenylation factors. However, we have not been able to assign one of the candidate poly(A) polymerases to a previously identified poly(A) polymerase. This simple fractionation procedure can be used for generating an in vitro reconstituted system for polyadenylation within a short period of time.

How the messenger got its tail: addition of poly(A) in the nucleus

Most mRNAs end in a poly(A) tail, the addition of which is catalysed by a poly(A) polymerase in conjunction with a distinct factor that provides specificity for mRNAs. The reaction is dynamic, involving separable initiation, elongation and termination phases. A companion article in next month's TIBS will review the regulation of poly(A) addition and removal during early animal development.

Tissue and species distribution of liver type and tumor type nuclear poly(A) polymerases

Previous studies in this laboratory have identified two distinct nuclear poly(A) polymerases, a 48 kDA tumor type enzyme and a 36-38 kDA liver type enzyme. To investigate the tissue and species specificity of these enzymes, nuclear extracts were prepared from various rat tissues, pig brain and two human cell lines. These as well as whole cell extract from yeast were probed for the two enzymes by immunoblot analysis using polyclonal anti-tumor poly(A) polymerase antibodies or autoimmune sera which contain antibodies specific for the liver type enzyme. Results indicate that both tumor and liver type enzymes are conserved across species ranging from rat to human. The yeast enzyme does not appear to be immunologically related to the liver or the tumor type poly(A) polymerase. The liver type enzyme appears to be specific for normal tissues whereas the tumor type enzyme is detected only in tissues in a "tumorigenic" state or cell lines originating from tumor tissues.