Biochemical and structural insights into substrate binding and catalytic mechanism of mammalian poly(A) polymerase

Polyadenylation of messenger RNA precursors is an essential process in eukaryotes. Poly(A) polymerase (PAP), a member of the nucleotidyltransferase family that includes DNA polymerase beta, incorporates ATP at the 3' end of mRNAs in a template-independent manner. Although the structures of mammalian and yeast PAPs are known, their mechanism of ATP selection has remained elusive. In a recent bovine PAP structure complexed with an analog of ATP and Mn2+, strictly conserved residues interact selectively with the adenine base, but the nucleotide was found in a "non-productive" conformation. Here we report a second bovine crystal structure, obtained in the presence of Mg2+, where 3'-dATP adopts a "productive" conformation similar to that seen in yeast PAP or DNA polymerase beta. Mutational analysis and activity assays with ATP analogs suggest a role in catalysis for one of the two adenine-binding sites revealed by our structural data. The other site might function to prevent futile hydrolysis of ATP. In order to investigate the role of metals in catalysis we performed steady state kinetics experiments under distributive polymerization conditions. These tests suggest a sequential random mechanism in vitro in the presence of ATP and RNA, without preference for a particular order of binding of the two substrates. In vivo, however, where polyadenylation is processive and the primer does not dissociate from the enzyme, an ordered mechanism with the primer as the leading substrate is more likely.     

PAPD5, a noncanonical poly(A) polymerase with an unusual RNA-binding motif

PAPD5 is one of the seven members of the family of noncanonical poly(A) polymerases in human cells. PAPD5 was shown to polyadenylate aberrant pre-ribosomal RNAs in vivo, similar to degradation-mediating polyadenylation by the noncanonical poly(A) polymerase Trf4p in yeast. PAPD5 has been reported to be also involved in the uridylation-dependent degradation of histone mRNAs. To test whether PAPD5 indeed catalyzes adenylation as well as uridylation of RNA substrates, we analyzed the in vitro properties of recombinant PAPD5 expressed in mammalian cells as well as in bacteria. Our results show that PAPD5 catalyzes the polyadenylation of different types of RNA substrates in vitro. Interestingly, PAPD5 is active without a protein cofactor, whereas its yeast homolog Trf4p is the catalytic subunit of a bipartite poly(A) polymerase in which a separate RNA-binding subunit is needed for activity. In contrast to the yeast protein, the C terminus of PAPD5 contains a stretch of basic amino acids that is involved in binding the RNA substrate.     

A unique system for regulating mitochondrial mRNA poly(A) status and stability in plants

Poly(A) status is the major determinant of mRNA stability, even in endosymbiotic organelles. Poly(A) specific ribonuclease (PARN) is distributed widely among eukaryotes and has been shown to regulate the poly(A) status of cytoplasmic mRNA in various organisms. Surprisingly, our recent study revealed that PARN also directly regulates poly(A) status of mitochondrial mRNA in Arabidopsis. In this addendum, we discuss whether this mitochondrial function of PARN is common in plants and why PARN has been assigned such a unique function.     

Cytoplasmic poly(ADP-ribose) polymerase and poly(ADP-ribose) glycohydrolase in AEV-transformed chicken erythroblasts

Poly(ADP-ribose) polymerase and poly(ADP-ribose) glycohydrolase activities were both investigated in chicken erythroblasts transformed by Avian Erythroblastosis Virus. Respectively 21% and 58% of these activities were found to be present in the post-mitochondrial supernatant (PMS). Fractionation of the PMS on sucrose gradients and poly(A⁺) mRNA detection by hybridization to [³H] poly(U) show that cytoplasmic poly(ADP-ribose) polymerase is exclusively localized in free mRNP. The glycohydrolase activity sedimented mostly in the 6 S region but 1/3 of the activity was in the free mRNP zone. Seven poly(ADP-ribose) protein acceptors were identified in the PMS in the Mr 21000–120000 range. The Mr 120000 protein corresponds to automodified poly(ADP-ribose) polymerase. A Mr 21000 protein acceptor is abundant in PMS and a Mr 34000 is exclusively associated with ribosomes and ribosomal subunits. The existence of both poly(ADP-ribose) polymerase and glycohydrolase activities in free mRNP argues in favour of a role of poly(ADP-ribosylation) in mRNP metabolism. A possible involvement of this post translational modification in the mechanisms of repression-derepression of mRNA is discussed.Abbreviations ADP-ribose adenosine (5) diphospho(5)--D ribose - poly(ADP-ribose) polymer of ADP-ribose - mRNP messenger ribonucleoprotein particles - PMSF phenylmethylsulfonyl fluoride - LDS lithium dodecyl sulfate - TCA trichloroacetic acid     

RNA-specific ribonucleotidyl transferases

RNA-specific nucleotidyl transferases (rNTrs) are a diverse family of template-independent polymerases that add ribonucleotides to the 3'-ends of RNA molecules. All rNTrs share a related active-site architecture first described for DNA polymerase beta and a catalytic mechanism conserved among DNA and RNA polymerases. The best known examples are the nuclear poly(A) polymerases involved in the 3'-end processing of eukaryotic messenger RNA precursors and the ubiquitous CCA-adding enzymes that complete the 3'-ends of tRNA molecules. In recent years, a growing number of new enzymes have been added to the list that now includes the noncanonical poly(A) polymerases involved in RNA quality control or in the readenylation of dormant messenger RNAs in the cytoplasm. Other members of the group are terminal uridylyl transferases adding single or multiple UMP residues in RNA-editing reactions or upon the maturation of small RNAs and poly(U) polymerases, the substrates of which are still not known. 2'-5'Oligo(A) synthetases differ from the other rNTrs by synthesizing oligonucleotides with 2'-5'-phosphodiester bonds de novo.     

Activatory effect of regucalcin on hepatic plasma membrane (Ca2+-Mg2+)-ATPase is impaired by liver injury with carbon tetrachloride administration in rats

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: 4486–1496, 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.     

一个独特的RNA酶A抗性复合物在腺病毒L1 poly(A)位点的上游形成

在腺病毒交替的ｐｏｌｙ（Ａ）位点使用过程中,靠近主要晚期启动子的Ｌ１ ｐｏｌｙ（Ａ）位点起着主导的作用。前期的实验已经发现,在Ｌ１ ｐｏｌｙ（Ａ）位点的上游存在一个ＲＮＡ的抑制元件叶ＵＲＥ,缺失ＵＲＥ可以使模拟小基因的ｐｏｌｙ（Ａ）进入病毒晚期的感染方式。现将Ｌ１ ｐｏｌｙ（Ａ）位点单独游离出来,用体外的紫外交联的方法对其进行研究,结果发现在没有紫外光照射的情况下,仍有一组小于３０ｋＤ独特的ＲＮＡ     

甲硫氨酸腺苷转移酶1A/2A平衡与肝细胞癌

肝细胞癌是一种死亡率极高的癌症,大多数病人发现时已属晚期.甲硫氨酸腺苷转移酶(MAT)是细胞生命活动的关键酶,可以通过催化甲酼氨酸和三磷酸腺苷(ATP)结合,促进生物甲基供体S-腺苷甲酼氨酸(SAMe)的生物合成.正常肝细胞中MAT1A与MAT2A存在动态平衡,共同维持细胞内SAMe稳态;肝细胞癌中MAT1A转变成MAT2A,会使SAMe生物合成减少,为癌细胞生长提供有利条件,故MAT1A表达降低而MAT2A增高.因此,促进MAT2A向MAT1A转化,进而提高MAT1A/MAT2A的比值可能成为治疗肝细胞癌的关键靶点之一.本文就MAT1A/MAT2A平衡在肝细胞癌中的重要作用作一综述,旨在为寻找肝细胞癌防治靶点提供新的思路.     

Maturation of mammalian H/ACA box snoRNAs: PAPD5-dependent adenylation and PARN-dependent trimming

Small nucleolar and small Cajal body RNAs (snoRNAs and scaRNAs) of the H/ACA box and C/D box type are generated by exonucleolytic shortening of longer precursors. Removal of the last few nucleotides at the 3' end is known to be a distinct step. We report that, in human cells, knock-down of the poly(A) specific ribonuclease (PARN), previously implicated only in mRNA metabolism, causes the accumulation of oligoadenylated processing intermediates of H/ACA box but not C/D box RNAs. In agreement with a role of PARN in snoRNA and scaRNA processing, the enzyme is concentrated in nucleoli and Cajal bodies. Oligo(A) tails are attached to a short stub of intron sequence remaining beyond the mature 3' end of the snoRNAs. The noncanonical poly(A) polymerase PAPD5 is responsible for addition of the oligo(A) tails. We suggest that deadenylation is coupled to clean 3' end trimming, which might serve to enhance snoRNA stability.     

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.     

Translational control by the poly(A) binding protein: A check for mRNA integrity

The eukaryotic mRNA 3′ poly(A) tail and the 5′ cap cooperate to synergistically enhance translation. This interaction is mediated by a ribonucleoprotein network that contains, at a minimum, the poly(A) binding protein (PABP), the cap-binding protein eIF4E, and a scaffolding protein, eIF4G. eIF4G, in turn, contains binding sites for eIF4A and eIF3, a 40S ribosome-associated initiation factor. The combined cooperative interactions within this “closed loop” mRNA among other effects enhance the affinity of eIF4E for the 5′ cap, by lowering its dissociation rate and, ultimately, facilitate the formation of 48S and 80S ribosome initiation complexes. The PABP-poly(A) interaction also stimulates initiation driven by picornavirus’ internal ribosomal entry sites (IRESs), a process that requires eIF4G but not eIF4E. PABP, therefore, should be considered a canonical initiation factor, integral to the formation of the initiation complex. Poly(A)-mediated translation is subjected to regulation by the PABP-interacting proteins Paip1 and Paip2. Paip1 acts as a translational enhancer. In contrast, Paip2 strongly inhibits translation by promoting dissociation of PABP from poly(A) and by competing with eIF4G for binding to PABP. Published in Russian in Molekulyarnaya Biologiya, 2006, Vol. 40, No. 4, pp. 684–693. The article is published in the original.     

Molecular flexibility and discontinuous translocation of a non-templated polymerase

Little is known regarding the translocation of non-templated nucleic acid polymerases with respect to single-stranded primers. VP55, the vaccinia virus poly(A) polymerase, translocates as it processively adds a approximately 3-7 adenylate tail to primers possessing only three ribouridylate residues (as an (rU)(2)-N(15)-rU motif), and a approximately 25-30 adenylate tail to primers that are more U-rich. Here, three models were addressed for the translocation of VP55 with respect to its primer, namely: (a) rigid protein/rigid nucleic acid; (b) flexible protein/rigid nucleic acid; (c) rigid protein/flexible nucleic acid. Analysis of free and covalently VP55-attached primers favored either (b) or a version of (c) incorporating a passive steric block, and suggested two regions of relative motion between polymerase and primer. Inclusion of a 6nt uridylate-rich patch at the primer 3' end switched the polymerase from approximately 3-7 nt to approximately 25-30 nt tail addition without affecting initial binding affinity. By synthesizing this patch as a (rU/dC) pool, discontinuous polymerase movements could be detected.     

Germ cell-specific gene 1 targets testis-specific poly(A) polymerase to the endoplasmic reticulum through protein-protein interactions

Testis-specific poly(A) polymerase (TPAP) is a cytoplasmic poly(A) polymerase that is highly expressed in round spermatids. We identified germ cell-specific gene 1 (GSG1) as a TPAP interaction partner protein using yeast two-hybrid and coimmunoprecipitation assays. Subcellular fractionation analysis showed that GSG1 is exclusively localized in the endoplasmic reticulum (ER) of mouse testis where TPAP is also present. In NIH3T3 cells cotransfected with TPAP and GSG1, both proteins colocalize in the ER. Moreover, expression of GSG1 stimulates TPAP targeting to the ER, suggesting that interactions between the two proteins lead to the redistribution of TPAP from the cytosol to the ER.     

Zinc binding catalytic domain of human tankyrase 1

Tankyrases are recently discovered proteins implicated in many important functions in the cell including telomere homeostasis and mitosis. Tankyrase modulates the activity of target proteins through poly(ADP-ribosyl)ation, and here we report the structure of the catalytic poly(ADP-ribose) polymerase (PARP) domain of human tankyrase 1. This is the first structure of a PARP domain from the tankyrase subfamily. The present structure reveals that tankyrases contain a short zinc-binding motif, which has not been predicted. Tankyrase activity contributes to telomere elongation observed in various cancer cells and tankyrase inhibition has been suggested as a potential route for cancer therapy. In comparison with other PARPs, significant structural differences are observed in the regions lining the substrate-binding site of tankyrase 1. These findings will be of great value to facilitate structure-based design of selective PARP inhibitors, in general, and tankyrase inhibitors, in particular.