Nuclear and chloroplast poly(A) polymerases from plants share a novel biochemical property.

Poly(A) polymerases are centrally involved in the process of mRNA 3' end formation in eukaryotes. In animals and yeast, this enzyme works as part of a large multimeric complex to add polyadenylate tracts to the 3' ends of precursor RNAs in the nucleus. Plant nuclear enzymes remain largely uncharacterized. In this report, we describe an initial analysis of plant nuclear poly(A) polymerases (nPAPs). An enzyme purified from pea nuclear extracts possesses many features that are seen with the enzymes from yeast and mammals. However, the pea enzyme possesses the ability to polyadenylate RNAs that are associated with polynucleotide phosphorylase (PNP), a chloroplast-localized enzyme involved in RNA turnover. Similar behavior is not seen with the yeast poly(A) polymerase (PAP). A fusion protein consisting of glutathione-S-transferase and the active domain of an Arabidopsis-encoded nuclear poly(A) polymerase was also able to utilize PNP, indicating that the activity of the pea enzyme was due to an interaction between the pea nPAP and PNP, and not to other factors that might copurify with the pea enzyme. These results suggest the existence, in plant nuclei, of factors related to PNP, and an interaction between such factors and poly(A) polymerases.

Nested PCR for ultrasensitive detection of the potato ring rot bacterium, Clavibacter michiganensis subsp. sepedonicus.

Oligonucleotide primers derived from sequences of the 16S rRNA gene (CMR16F1, CMR16R1, CMR16F2, and CMR16R2) and insertion element IS1121 of Clavibacter michiganensis subsp. sepedonicus (CMSIF1, CMSIR1, CMSIF2, and CMISR2) were used in nested PCR to detect the potato ring rot bacterium C. michiganensis subsp. sepedonicus. Nested PCR with primer pair CMSIF1-CMSIR1 followed by primer pair CMSIF2-CMSIR2 specifically detected C. michiganensis subsp. sepedonicus, while nested PCR with CMR16F1-CMR16R1 followed by CMR16F2-CMR16R2 detected C. michiganensis subsp. sepedonicus and the other C. michiganensis subspecies. In the latter case, C. michiganensis subsp. sepedonicus can be differentiated from the other subspecies by restriction fragment length polymorphism (RFLP) analyses of the nested PCR products (16S rDNA sequences). The nested PCR assays developed in this work allow ultrasensitive detection of very low titers of C. michiganensis subsp. sepedonicus which may be present in symptomiess potato plants or tubers and which cannot be readily detected by direct PCR (single PCR amplification). RFLP analysis of PCR products provides for an unambiguous confirmation of the identify of C. michiganensis subsp. sepedonicus.

Several distinct types of sequence elements are required for efficient mRNA 3' end formation in a pea rbcS gene.

We have conducted an extensive linker substitution analysis of the polyadenylation signal from a pea rbcS gene. From these studies, we can identify at least two, and perhaps three, distinct classes of cis element involved in mRNA 3' end formation in this gene. One of these, termed the far-upstream element, is located between 60 and 120 nt upstream from its associated polyadenylation sites and appears to be largely composed of a series of UG motifs. A second, termed the near-upstream element, is more proximate to poly(A) sites and may be functionally analogous to the mammalian polyadenylation signal AAUAAA, even though the actual sequences involved may not be AAUAAA. The third possible class is the putative cleavage and polyadenylation site itself. We find that the rbcS-E9 far-upstream element can replace the analogous element in another plant polyadenylation signal, that from cauliflower mosaic virus, and that one near-upstream element can function with either of two poly(A) sites. Thus, these different cis elements are largely interchangeable. Our studies indicate that a cellular plant gene possesses upstream elements distinct from AAUAAA that are involved in mRNA 3' end formation and that plant genes probably have modular, multicomponent polyadenylation signals.

Characterization of the polyadenylation signal from the T-DNA-encoded octopine synthase gene.

We have characterized the polyadenylation signal from the octopine synthase (ocs) gene. This signal directs mRNA 3' end formation at a number of distinct sites. A combination of deletion and linker-substitution analyses revealed that each of these sites is controlled by multiple upstream sequence elements. Upstream sequences relatively far (greater than 80 nt) from the ocs poly[A] sites were found to be needed for functioning of these sites. Upstream sequences nearer to poly [A] sites were also found to be involved in mRNA 3' end formation in the ocs gene. In addition, a set of novel elements that mediates 3' end choice was uncovered by deletion analysis of sequences downstream from the ocs polyadenylation sites. Our experiments indicate mRNA 3' end formation in the ocs is controlled by a complex series of cis-acting signals, and suggest that the process of mRNA 3' end formation might be linked to transcription termination.

The SV40 small t intron is accurately and efficiently spliced in tobacco cells.

We have introduced the SV40 small t intron into tobacco cells as part of a cauliflower mosaic virus 35S promoter-chloramphenicol acetyltransferase-SV40 transcription unit. We find that the small t intron is efficiently and accurately spliced in transgenic tobacco cells that carry this transcription unit. Our results indicate that there is substantial conservation of RNA processing signals between plants and animals, more than has been previously assumed. They also suggest that pre-mRNA processing in plants requires multiple branch sites for efficient processing.

Upstream sequences other than AAUAAA are required for efficient messenger RNA 3'-end formation in plants.

We have characterized the upstream nucleotide sequences involved in mRNA 3'-end formation in the 3' regions of the cauliflower mosaic virus (CaMV) 19S/35S transcription unit and a pea gene encoding ribulose-1,5-bisphosphate carboxylase small subunit (rbcS). Sequences between 57 bases and 181 bases upstream from the CaMV polyadenylation site were required for efficient polyadenylation at this site. In addition, an AAUAAA sequence located 13 bases to 18 bases upstream from this site was also important for efficient mRNA 3'-end formation. An element located between 60 bases and 137 bases upstream from the poly(A) addition sites in a pea rbcS gene was needed for functioning of these sites. The CaMV -181/-57 and rbcS -137/-60 elements were different in location and sequence composition from upstream sequences needed for polyadenylation in mammalian genes, but resembled the signals that direct mRNA 3'-end formation in yeast. However, the role of the AAUAAA motif in 3'-end formation in the CaMV 3' region was reminiscent of mRNA polyadenylation in animals. We suggest that multiple elements are involved in mRNA 3'-end formation in plants, and that interactions of different components of the plant polyadenylation apparatus with their respective sequence elements and with each other are needed for efficient mRNA 3'-end formation.

Homology of pCS1 Plasmid Sequences with Chromosomal DNA in Clavibacter michiganense subsp. sepedonicum: Evidence for the Presence of a Repeated Sequence and Plasmid Integration.

Restriction fragments of pCS1, a 50.6-kilobase (kb) plasmid present in many strains of Clavibacter michiganense subsp. sepedonicum ("Corynebacterium sepedonicum"), have been cloned in an M13mp11 phage vector. Radiolabeled forms of these cloned fragments have been used as Southern hybridization probes for the presence of plasmid sequences in chromosomal DNA of this organism. These studies have shown that all tested strains lacking the covalently closed circular form of pCS1 contain the plasmid in integrated form. In each case the site of integration exists on a single plasmid restriction fragment with a size of 5.1 kb. Southern hybridizations with these probes have also revealed the existence of a major repeated sequence in C. michiganense subsp. sepedonicum. Hybridizations of chromosomal DNA with deletion subclones of a 2.9-kb plasmid fragment containing the repeated sequence indicate that the size of the repeated sequence is approximately 1.3 kb. One of the copies of the repeated sequence is on the plasmid fragment containing the site of integration.