Alternative translation initiation augments the human mitochondrial proteome.

Alternative translation initiation (ATI) is a mechanism of producing multiple proteins from a single transcript, which in some cases regulates trafficking of proteins to different cellular compartments, including mitochondria. Application of a genome-wide computational screen predicts a cryptic mitochondrial targeting signal for 126 proteins in mouse and man that is revealed when an AUG codon located downstream from the canonical initiator methionine codon is used as a translation start site, which we term downstream ATI (dATI). Experimental evidence in support of dATI is provided by immunoblotting of endogenous truncated proteins enriched in mitochondrial cell fractions or of co-localization with mitochondria using immunocytochemistry. More detailed cellular localization studies establish mitochondrial targeting of a member of the cytosolic poly(A) binding protein family, PABPC5, and of the RNA/DNA helicase PIF1α. The mitochondrial isoform of PABPC5 co-immunoprecipitates with the mitochondrial poly(A) polymerase, and is markedly reduced in abundance when mitochondrial DNA and RNA are depleted, suggesting it plays a role in RNA metabolism in the organelle. Like PABPC5 and PIF1α, most of the candidates identified by the screen are not currently annotated as mitochondrial proteins, and so dATI expands the human mitochondrial proteome.

Preliminary crystallographic analysis of a polyadenylate synthase from Megavirus.

Megavirus chilensis, a close relative of the Mimivirus giant virus, is also the most complex virus sequenced to date, with a 1.26 Mb double-stranded DNA genome encoding 1120 genes. The two viruses share common regulatory elements such as a peculiar palindrome governing the termination/polyadenylation of viral transcripts. They also share a predicted polyadenylate synthase that presents a higher than average percentage of residue conservation. The Megavirus enzyme Mg561 was overexpressed in Escherichia coli, purified and crystallized. A 2.24 Šresolution MAD data set was recorded from a single crystal on the ID29 beamline at the ESRF.

Identification and characterization of nuclear non-canonical poly(A) polymerases from Trypanosoma brucei.

Regulation of nuclear genome expression in Trypanosoma brucei is critical for this protozoan parasite's successful transition between its vertebrate and invertebrate host environments. The canonical eukaryotic circuits such as modulation of transcription initiation, mRNA splicing and polyadenylation appear to be nearly non-existent in T. brucei suggesting that the transcriptome is primarily defined by mRNA turnover. Our previous work has highlighted sequence similarities between terminal RNA uridylyl transferases (TUTases) and non-canonical poly(A) polymerases, which are widely implicated in regulating nuclear, cytoplasmic and organellar RNA decay throughout the eukaryotic lineage. Here, we have continued characterization of TUTase-like proteins in T. brucei and identified two nuclear non-canonical poly(A) polymerases (ncPAPs). The 82kDa TbncPAP1 is essential for viability of procyclic and bloodstream forms of T. brucei. Similar to Trf4/5 proteins from budding yeast, TbncPAP1 requires protein cofactor(s) to exert poly(A) polymerase activity in vitro. The recombinant 54kDa TbncPAP2 showed a PAP activity as an individual polypeptide. Proteomic analysis of the TbncPAP1 interactions demonstrated its association with Mtr4 RNA helicase and several RNA binding proteins, including a potential ortholog of Air1p/2p proteins, which indicates the presence of a stable TRAMP-like complex in trypanosomes. Our findings suggest that TbncPAP1 may be a "quality control" nuclear PAP involved in targeting aberrant or anti-sense transcripts for degradation by the 3'-exosome. Such mechanisms are likely to play a major role in alleviating promiscuity of the transcriptional machinery.

Symplekin and xGLD-2 are required for CPEB-mediated cytoplasmic polyadenylation.

Cytoplasmic polyadenylation-induced mRNA translation is a hallmark of early animal development. In Xenopus oocytes, where the molecular mechanism has been defined, the core factors that control this process include CPEB, an RNA binding protein whose association with the CPE specifies which mRNAs undergo polyadenylation; CPSF, a multifactor complex that interacts with the near-ubiquitous polyadenylation hexanucleotide AAUAAA; and maskin, a CPEB and eIF4E binding protein whose regulation of initiation is governed by poly(A) tail length. Here, we define two new factors that are essential for polyadenylation. The first is symplekin, a CPEB and CPSF binding protein that serves as a scaffold upon which regulatory factors are assembled. The second is xGLD-2, an unusual poly(A) polymerase that is anchored to CPEB and CPSF even before polyadenylation begins. The identification of these factors has broad implications for biological process that employ polyadenylation-regulated translation, such as gametogenesis, cell cycle progression, and synaptic plasticity.

Evidence of two forms of poly(A) polymerase in germinated wheat embryos and their regulation by a novel protein kinase.

Two forms of poly(A) polymerase (PAPI and PAPII) from germinated wheat embryos have been resolved on DEAE-cellulose ion-exchange chromatography by a linear gradient of 0-500 mM (NH(4))(2)SO(4). Further purification shows that both forms are monomeric in nature with an identical molecular weight, approximately 65 kDa. The phosphoprotein nature of PAPI and PAPII has been established by in vivo labelling with (32)P-orthophosphate. Acid hydrolysis of both (32)P-labelled purified PAPI and PAPII has revealed that phosphorylations generally take place in serine and threonine residues. PAPI and PAPII have also been characterised with respect to V(max) and K(m) for poly(A). The V(max) and K(m) values of PAPI are 28.57 and 11.37 microg, respectively, whereas 34.48 and 7.04 microg of PAPII. In vitro dephosphorylation of the purified enzyme by alkaline phosphatase leads to a significant loss of the enzyme activity, which is regained upon phosphorylation by a 65 kDa protein kinase (PK) purified from wheat embryos. The extent of phosphorylation by protein kinase shows that PK has similar affinity towards both PAPI and PAPII, whereas the phosphate incorporation in PAPII is twofold higher than PAPI suggesting their distinct chemical nature.

Cid13 is a cytoplasmic poly(A) polymerase that regulates ribonucleotide reductase mRNA.

Fission yeast Cid13 and budding yeast Trf4/5 are members of a newly identified nucleotidyltransferase family conserved from yeast to man. Trf4/5 are thought to be essential DNA polymerases. We report that Cid13 is a poly(A) polymerase. Unlike conventional poly(A) polymerases, which act in the nucleus and indiscriminately polyadenylate all mRNA, Cid13 is a cytoplasmic enzyme that specifically targets suc22 mRNA that encodes a subunit of ribonucleotide reductase (RNR). cid13 mutants have reduced dNTP pools and are sensitive to hydroxyurea, an RNR inhibitor. We propose that Cid13 defines a cytoplasmic form of poly(A) polymerase important for DNA replication and genome maintenance.

Drug action on poly(A) polymerase activity and isoforms during U937 cell apoptosis.

The enzyme poly(A) polymerase (PAP; EC 2.7.7.19) catalyzes the polyadenylation of mRNAs. It's activity levels and isoforms vary within the cell cycle (31) and apoptosis (34). The direct effect of most anticancer drugs is cell damage (DNA and RNA synthesis inhibition, DNA breaks and/or cell cycle aberrations), which then triggers signaling pathways that activate apoptosis and eventually lead to regulated cell death. The experiments described here concern the chemotherapeutic agents, interferon (IFN) and 5-fluorouracil (5-FU), and their action on U937 cells, alone or in various combinations, resulting in the commitment of cell apoptosis, as observed by the appearance of DNA fragmentation. Furthermore, examination of U937 cell apoptotic trend in parallel with PAP activity measurements and isoforms detection by immunoblotting, revealed both partial enzyme inactivation and dephosphorylation, in particular after the combined drug action of 5-FU and IFN on U937 cells. Our work on chemotherapeutic drug action at the level of mRNA polyadenylation may contribute to new insights into the mechanism of cell apoptosis, as well as provide information on mRNA poly(A) tail formation, removal and function.

Auxin regulated poly(A)polymerase activity in Cicer arietinum epicotyls.

There was a linear increase in poly (A+) polymerase activity in the C. arietinum epicotyls during germination. Six-day-old auxin treated seedlings showed about 3-4 fold stimulation in enzyme activity, accompanied with 3- fold rise in the relative abundance of poly (A+) RNA levels. Actinomycin D, cycloheximide, cordycepin and amino acid analogues caused dramatic decline in poly (A+) polymerase as well as poly (A+) RNA levels. It seems that auxin induced a de novo synthesis of this enzyme.

Large-scale production and purification of recombinant protein from an insect cell/baculovirus system in Erlenmeyer flasks: application to the chicken poly(ADP-ribose) polymerase catalytic domain.

A simple and inexpensive shaker/Erlenmeyer flask system for large-scale cultivation of insect cells is described and compared to a commercial spinner system. On the basis of maximum cell density, average population doubling time and overproduction of recombinant protein, a better result was obtained with a simpler and less expensive bioreactor consisting of Erlenmeyer flasks and an ordinary shaker waterbath. Routinely, about 90 mg of pure poly(ADP-ribose) polymerase catalytic domain was obtained for a total of 3 x 10(9) infected cells in three liters of culture.

Large-scale production and purification of recombinant protein from an insect cell/baculovirus system in Erlenmeyer flasks: application to the chicken poly(ADP-ribose) polymerase catalytic domain

A simple and inexpensive shaker/Erlenmeyer flask system for largescale cultivation of insect cells is described and compared to a commercial spinner system. On the basis of maximum cell density, average population doubling time and overproduction of recombinant protein, a better result was obtained with a simpler and less expensive biorector consisting of Erlenmeyer flasks and an ordinary shaker waterbath. Routinely, about 90 mg of pure poly(ADP-ribose) polymerase catalytic domain was obtained for a total of 3 x 10(9) infected cells in three liters of culture.

Purification and characterization of full-length mammalian poly(A) polymerase.

Bovine poly(A) polymerase was purified from overexpressing strains of Escherichia coli and from Spodoptera frugiperda Sf21 cells infected with a recombinant baculovirus. The E. coli-expressed enzyme had an apparent molecular mass of 85 kDa in SDS gels, as anticipated from the cDNA sequence. Poly(A) polymerase from insect cells consisted of several species with higher apparent molecular weights due to phosphorylation. The two preparations showed minor differences in their catalytic properties. The insect cell-expressed enzyme had a 5-fold higher Km for the primer in a nonspecific Mn(2+)-dependent polyadenylation reaction and a lower activity in specific AAUAAA-dependent polyadenylation and generated shorter poly(A) tails during the processive phase of polyadenylation. Both recombinant poly(A) polymerases stimulated 3'-cleavage of the SV40 late mRNA precursor. Neither preparation contained ATPase or poly(A) degrading activity. The enzyme polymerized adenosine 5'-O-(1-thiotriphosphate), SP-diastereomer, with inversion of configuration. Thus, poly(A) synthesis proceeds via an SN2-in-line mechanism without covalent intermediate.

Biochemical and immunological identification and enrichment of poly(A) polymerase from human thymus.

Human thymus poly(A) polymerase (EC 2.7.7.19) activity has been investigated using poly(A) and oligo(A) as initiators. All obtained fractions reveal more than one polypeptide as detected by immunoblotting after SDS-PAGE. In addition to the homogeneously purified (Tsiapalis et al., J Biol Chem 250: 4486-4496, 1975 and Wahle, J Biol Chem 266: 3131-3139, 1991), about 60 kDa polypeptide, a larger polypeptide, about 80 kDa, that comigrates in the region of poly(A) polymerase activity was detected, enriched and partially characterized; it appears having similar size with bovine poly(A) polymerase cloned in E. coli. Polyclonal antiserum produced against recombinant bovine poly(A) polymerase reacts more efficiently with the about 80 kDa polypeptide upon immunoblotting, and can precipitate the poly(A) polymerase activity. This enzyme form, from human tissue, is novel in terms of size and may reflect intact or physiological form of poly(A) polymerase in human thymus, and supports and substantiates recent reports on the enzyme from other sources.

Poly (A) polymerases in the nucleus and cytoplasm of frog oocytes: dynamic changes during oocyte maturation and early development.

Poly(A) can be added to mRNAs both in the nucleus and in the cytoplasm. During oocyte maturation and early embryonic development, cytoplasmic polyadenylation of preexisting mRNAs provides a common mechanism of translational control. In this report, to begin to understand the regulation of polyadenylation activities during early development, we analyze poly (A) polymerases (PAPs) in oocytes and early embryos of the frog, Xenopus laevis. We have cloned and sequenced a PAP cDNA that corresponds to a maternal mRNA present in frog oocytes. This PAP is similar in size and sequence to mammalian nuclear PAPs. By immunoblotting using monoclonal antibodies raised against human PAP, we demonstrate that oocytes contain multiple forms of PAP that display different electrophoretic mobilities. The oocyte nucleus contains primarily the slower migrating forms of PAP, whereas the cytoplasm contains primarily the faster migrating species. The nuclear forms of PAP are phosphorylated, accounting for their retarded mobility. During oocyte maturation and early postfertilization development, preexisting PAPs undergo regulated phosphorylation and dephosphorylation events. Using the cloned PAP cDNA, we demonstrate that the complex changes in PAP forms seen during oocyte maturation may be due to modifications of a single polypeptide. These results demonstrate that the oocyte contains a cytoplasmic polymerase closely related to the nuclear enzyme and suggest models for how its activity may be regulated during early development.

Cloning and characterization of a Xenopus poly(A) polymerase.

During oocyte maturation and early embryogenesis in Xenopus laevis, the translation of several mRNAs is regulated by cytoplasmic poly(A) elongation, a reaction catalyzed by poly(A) polymerase (PAP). We have cloned, sequenced, and examined several biochemical properties of a Xenopus PAP. This protein is 87% identical to the amino-terminal portion of bovine PAP, which catalyzes the nuclear polyadenylation reaction, but lacks a large region of the corresponding carboxy terminus, which contains the nuclear localization signal. When injected into oocytes, the Xenopus PAP remains concentrated in the cytoplasm, suggesting that it is a specifically cytoplasmic enzyme. Oocytes contain several PAP mRNA-related transcripts, and the levels of at least the one encoding the putative cytoplasmic enzyme are relatively constant in oocytes and early embryos but decline after blastulation. When expressed in bacteria and purified by affinity and MonoQ-Sepharose chromatography, the protein has enzymatic activity and adds poly(A) to a model substrate. Importantly, affinity-purified antibodies directed against Xenopus PAP inhibit cytoplasmic polyadenylation in egg extracts. These data suggest that the PAP described here could participate in cytoplasmic polyadenylation during Xenopus oocyte maturation.

Multiple forms of poly(A) polymerases in human cells.

We have cloned human poly(A) polymerase (PAP) mRNA as cDNA in Escherichia coli. The primary structure of the mRNA was determined and compared to the bovine PAP mRNA sequence. The two sequences were 97% identical at the nucleotide level, which translated into 99% similarity at the amino acid level. Polypeptides representing recombinant PAP were expressed in E. coli, purified, and used as antigens to generate monoclonal antibodies. Western blot analysis using these monoclonal antibodies as probes revealed three PAPs, having estimated molecular masses of 90, 100, and 106 kDa in HeLa cell extracts. Fractionation of HeLa cells showed that the 90-kDa polypeptide was nuclear while the 100- and 106-kDa species were present in both nuclear and cytoplasmic fractions. The 106-kDa PAP was most likely a phosphorylated derivative of the 100-kDa species. PAP activity was recovered in vitro by using purified recombinant human PAP. Subsequent mutational analysis revealed that both the N- and C-terminal regions of PAP were important for activity and suggested that cleavage and polyadenylylation specificity factor (CPSF) interacted with the C-terminal region of PAP. Interestingly, tentative phosphorylation sites have been identified in this region, suggesting that phosphorylation/dephosphorylation may regulate the interaction between the two polyadenylylation factors PAP and CPSF.

Identification of a second poly(A) polymerase in Escherichia coli.

A second poly(A) polymerase (PAP II) has been identified in Escherichia coli using a strain carrying a deletion of pcnB (the structural gene for PAP I; Cao and Sarkar, 1992b) and pnp-7 (a null mutation in the structural gene for polynucleotide phosphorylase). While PAP I has a M(r) of 53,000, PAP II is a smaller protein with a native M(r)-35,000. PAP II differs from PAP I in preferring poly(A) over tRNA primers and being more thermolabile. The presence of multiple poly(A) polymerases in E. coli raises interesting questions regarding the role of polyadenylation in mRNA synthesis and decay.

Polyadenylation of maternal mRNA during oocyte maturation: poly(A) addition in vitro requires a regulated RNA binding activity and a poly(A) polymerase.

Specific maternal mRNAs receive poly(A) during early development as a means of translational regulation. In this report, we investigated the mechanism and control of poly(A) addition during frog oocyte maturation, in which oocytes advance from first to second meiosis becoming eggs. We analyzed polyadenylation in vitro in oocyte and egg extracts. In vivo, polyadenylation during maturation requires AAUAAA and a U-rich element. The same sequences are required for polyadenylation in egg extracts in vitro. The in vitro reaction requires at least two separable components: a poly(A) polymerase and an RNA binding activity with specificity for AAUAAA and the U-rich element. The poly(A) polymerase is similar to nuclear poly(A) polymerases in mammalian cells. Through a 2000-fold partial purification, the frog egg and mammalian enzymes were found to be very similar. More importantly, a purified calf thymus poly(A) polymerase acquired the sequence specificity seen during frog oocyte maturation when mixed with the frog egg RNA binding fraction, demonstrating the interchangeability of the two enzymes. To determine how polyadenylation is activated during maturation, we compared polymerase and RNA binding activities in oocyte and egg extracts. Although oocyte extracts were much less active in maturation-specific polyadenylation, they contained nearly as much poly(A) polymerase activity. In contrast, the RNA binding activity differed dramatically in oocyte and egg extracts: oocyte extracts contained less binding activity and the activity that was present exhibited an altered mobility in gel retardation assays. Finally, we demonstrate that components present in the RNA binding fraction are rate-limiting in the oocyte extract, suggesting that fraction contains the target that is activated by progesterone treatment. This target may be the RNA binding activity itself. We propose that in spite of the many biological differences between them, nuclear polyadenylation and cytoplasmic polyadenylation during early development may be catalyzed by similar, or even identical, components.

Identification of the gene for an Escherichia coli poly(A) polymerase.

Many bacterial mRNAs, like those of eukaryotes, carry a polyadenylate sequence at their 3' termini, but neither the function of the bacterial poly(A) moieties nor their biosynthesis have been elucidated. To develop a genetic tool to approach the problem of bacterial poly(A) RNA, we have sought to identify the genes responsible for mRNA polyadenylylation. A poly(A) polymerase was purified to homogeneity from extracts of Escherichia coli and subjected to N-terminal sequence analysis. The 25-residue amino acid sequence obtained was used to design primers for the amplification of the corresponding coding region by the PCR from an E. coli DNA template. A 74-base-pair DNA segment was obtained that matched a region in the pcnB locus of E. coli, a gene that had originally been identified as controlling plasmid copy number [J. Lopilato, S. Bortner & J. Beckwith (1986) Mol. Gen. Genet. 205, 285-290] and was subsequently cloned and sequenced [J. Liu & J. S. Parkinson (1989) J. Bacteriol. 171, 1254-1261]. Direct evidence that the pcnB locus encodes poly(A) polymerase was provided by the observation that a bacterial strain transformed with an inducible expression vector carrying pcnB as a translational fusion produced 100-fold elevated levels of poly(A) polymerase upon induction. No increased poly(A) polymerase activity was observed in cells transformed with expression vectors carrying truncated forms of the pcnB gene. The identification of a gene encoding bacterial poly(A) polymerase opens the way for the study of the biosynthesis and function of bacterial polyadenylylated mRNA.

Separation of factors required for cleavage and polyadenylation of yeast pre-mRNA.

Cleavage and polyadenylation of yeast precursor RNA require at least four functionally distinct factors (cleavage factor I [CF I], CF II, polyadenylation factor I [PF I], and poly(A) polymerase [PAP]) obtained from yeast whole cell extract. Cleavage of precursor occurs upon combination of the CF I and CF II fractions. The cleavage reaction proceeds in the absence of PAP or PF I. The cleavage factors exhibit low but detectable activity without exogenous ATP but are stimulated when this cofactor is included in the reaction. Cleavage by CF I and CF II is dependent on the presence of a (UA)6 sequence upstream of the GAL7 poly(A) site. The factors will also efficiently cleave precursor with the CYC1 poly(A) site. This RNA does not contain a UA repeat, and processing at this site is thought to be directed by a UAG...UAUGUA-type motif. Specific polyadenylation of a precleaved GAL7 RNA requires CF I, PF I, and a crude fraction containing PAP activity. The PAP fraction can be replaced by recombinant PAP, indicating that this enzyme is the only factor in this fraction needed for the reconstituted reaction. The poly(A) addition step is also dependent on the UA repeat. Since CF I is the only factor necessary for both cleavage and poly(A) addition, it is likely that this fraction contains a component which recognizes processing signals located upstream of the poly(A) site. The initial separation of processing factors in yeast cells suggests both interesting differences from and similarities to the mammalian system.