Qingshun Li

Polynucleotide Phosphorylase Is a Component of a Novel Plant Poly(A) Polymerase

We have isolated cDNA clones encoding a novel RNA-binding protein that is a component of a multisubunit poly(A) polymerase from pea seedlings. The encoded protein bears a significant resemblance to polynucleotide phosphorylases (PNPases) from bacteria and chloroplasts. More significantly, this RNA-binding protein is able to degrade RNAs with the resultant production of nucleotide diphosphates, and it can add extended polyadenylate tracts to RNAs using ADP as a donor for adenylate moieties. These activities are characteristic of PNPase. Antibodies raised against the cloned protein simultaneously immunoprecipitate both poly(A) polymerase and PNPase activity. We conclude from these studies that PNPase is the RNA-binding cofactor for this poly(A) polymerase and is an integral player in the reaction catalyzed by this enzyme. The identification of this RNA-binding protein as PNPase, which is a chloroplast-localized enzyme known to be involved in mRNA 3′-end determination and turnover (Hayes, R., Kudla, J., Schuster, G., Gabay, L., Maliga, P., and Gruissem, W. (1996) EMBO J. 15, 1132–1141), raises interesting questions regarding the subcellular location of the poly(A) polymerase under study. We have reexamined this issue, and we find that this enzyme can be detected in chloroplast extracts. The involvement of PNPase in polyadenylation in vitro provides a biochemical rationale for the link between chloroplast RNA polyadenylation and RNA turnover which has been noted by others (Lisitsky, I., Klaff, P., and Schuster, G. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 13398–13403).

A near-upstream element in a plant polyadenylation signal consists of more than six nucleotides

A plant polyadenylation signal consists of three distinct components: a far-upstream element (FUE) that can control utilization of several polyadenylation sites, one or more near-upstream elements (NUEs) that control utilization of each site in a transcription unit, and polyadenylation site (CSs) themselves. NUEs have previously been suggested to be related to the mammalian polyadenylation signal AAUAAA. However, many plant genes do not contain AAUAAA-like motifs near their polyadenylation sites. To better understand the nature of NUEs, we conducted a systematic analysis of the NUE for one polyadenylation site (site 1) in the pea rbcS-E9 gene; this NUE lacks an AAUAAA motif. Linker substitution studies showed that the NUE for site 1 in this gene resides in the sequence AAAUGGAAA. Single-nucleotide substitutions in this domain had modest effects on the functioning of this NUE. Replacement of part of this sequence with the sequence AAUAAA increased the efficiency of this NUE. However, alteration of nucleotides immediately 3′ of the AAUAAA reversed this effect. Our results indicate that the NUE for site 1 consists of as many as 9 nucleotides, that these 9 bases do not include an element that is intolerant of single base changes, that the sequence AAUAAA can function as a NUE for site 1, and that sequences flanking AAUAAA can affect the efficiency of functioning as a NUE.

A Plant Poly(A) Polymerase Requires a Novel RNA-binding Protein for Activity

We have purified a novel factor (PAP-III) that is a component of a multisubunit poly(A) polymerase from pea seedlings. This factor consists of one or more polypeptides with molecular masses of about 105 kDa and of a population of associated RNAs that can serve as substrates for polyadenylation. When these RNAs are separated from the 105-kDa polypeptides, polyadenylation becomes dependent upon exogenously added RNA. This RNA-dependent activity does not require the presence of a polyadenylation signal in the substrate, indicating that the activity under study is a nonspecific polyadenylation activity. One or more of the 105-kDa polypeptides could be cross-linked to the products of polyadenylation labeled with [α-32P]ATP and to exogenously added labeled RNAs. Cross-linking of the 105-kDa polypeptides to the products of polyadenylation was not affected by the presence of exogenously added competitors, whereas cross-linking to exogenous RNAs was diminished by excesses of RNA homopolymers. Exogenous RNAs could be polyadenylated by the combination of PAP-I + PAP-III, and this activity was diminished if the binding of the exogenous RNAs to PAP-III was prevented. We conclude from these studies that PAP-III is an RNA binding protein, that polyadenylation by the poly(A) polymerase occurs while the substrate RNAs are associated with this protein, and that the pea poly(A) polymerase can only polyadenylate those RNAs that are associated with PAP-III.

Characterization of a novel plant poly(A) polymerase

We have purified and characterized poly(A) polymerases (PAPs) from Pisum sativum, Brassica juncea, and Zea mays. Through chromatography on DEAE-Sepharose and heparin-Sepharose, these PAPs copurified as a single enzyme along with RNPs that could provide RNA substrates for the enzyme. More extensive purification by chromatography on MonoQ resulted in the resolution of the PAPs into as many as three fractions. One of these (PAP-I) contained a 43-kDa polypeptide immunologically related to the yeast PAP, and two others (PAP-II and PAP-III) contained RNAs that could serve as substrates for polyadenylation. These fractions by themselves possessed little PAP activity, but mixtures containing combinations of these displayed substantial activity. Similar PAP factors (PAP-I and PAP-III) were identified after fractionation of extracts prepared from Brassica juncea and Zea mays. The factors from one plant were completely interchangeable with those from different plants. We conclude that the poly(A) polymerases present in vegetative plant tissues consist of more than one component. In this respect, they are substantially different from other reported plant, mammalian, and yeast PAPs.

Characterization of a cDNA encoding a novel plant poly(A) polymerase

We have isolated cDNA clones encoding a novel factor (PAP-I) that is a component of a multi-subunit poly(A) polymerase from pea seedlings. The encoded protein, when isolated from appropriately engineered Escherichia coli, was active as a poly(A) polymerase, either with an associated RNA binding cofactor (PAP-III) or with free poly(A) as an RNA substrate. The latter observation indicates that PAP-I is in fact a poly(A) polymerase. PAP-I bore a striking resemblance to an as yet uncharacterized cyanobacterial protein. This observation suggested a possible chloroplast localization for PAP-I. This hypothesis was tested and found to be substantiated; immunoblot analysis identified PAP-I in chloroplast but not nuclear extracts. Our results suggest that PAP-I is a component of the machinery that adds poly(A) to chloroplast RNAs.

Identification and Characterization of Two Distinctive RNA Binding Activities in Pea Nuclear Extracts

We have identified and purified two RNA binding factors from pea nuclear extracts. One factor (RBF-1) consisted of at least two polypeptides with molecular weights of approximately 27 and 59 kD; each of these polypeptides could be crosslinked to labelled RNA by ultraviolet light. The other factor (RBF-2) also consisted of two polypeptides (of approximately 93 and 126 kO in size) that could be crosslinked to RNA by UV. Both factors showed general preferences for single stranded RNA. However, RBF-1 displayed a preference for poly(A) and poly(U) over poly(G) or poly(C), while RBF-2 had a strong preference for poly(U) over the other three homo polymers. These properties are suggestive of possible roles for these factors in RNA metabolism in plant nuclei.