Amplification of plant U3 and U6 snRNA gene sequences using primers specific for an upstream promoter element and conserved intragenic regions.

U-snRNA genes in higher plants contain two essential promoter elements, the USE with sequence RTCCCACATCG and the TATA-like box, positioned in the -70 and -30 regions, respectively. Using an oligodeoxynucleotide containing the USE motif and oligodeoxynucleotides specific for the intragenic regions conserved in U-snRNAs, several sequences encoding U6 and U3 snRNAs were determined by polymerase chain reaction (PCR) amplification of Arabidopsis thaliana and tobacco genomic DNAs. This method provides a simple and rapid procedure for characterisation of plant U-snRNA genes and their promoters. It could also be used for the characterisation of other genes containing conserved upstream promoter elements. PCR-derived fragments were used as probes for the isolation of the U3 snRNA genes from a genomic library of Arabidopsis. Two isolated U3 genes were shown to be active when transfected into protoplasts of Nicotiana plumbaginifolia. Both U3 genes contain the USE and TATA-like upstream elements located in similar positions to the U6 genes of Arabidopsis. The encoded Arabidopsis U3 snRNAs can be folded into a secondary structure which is more similar to that of U3 RNAs from lower eukaryotes rather than from metazoa.     

7-2/MRP RNAs in plant and mammalian cells: association with higher order structures in the nucleolus.

Mammalian MRP (for mitochondrial RNA processing) RNA, also known as 7-2 RNA, is a nuclear encoded small RNA which has been reported to function in two different cellular compartments: in the mitochondria and in the nucleus. The ribonucleoprotein particle which contains the 7-2/MRP RNA, called RNase MRP, has ribonucleolytic activity and shares some structural similarity with RNase P. It has been proposed that in mitochondria, the RNase MRP is responsible for endonucleolytic cleavage of primer RNA during DNA replication. We have characterized the gene and cDNAs encoding 7-2/MRP-like RNA in Arabidopsis and tobacco, and found that in plants this RNA is enriched in nucleoli but is undetectable in purified mitochondria isolated from tobacco leaves or cells grown in suspension. In glycerol gradients tobacco 7-2/MRP RNA cosediments with large approximately 80S structures possibly representing ribosomal precursors. Fractionation of HeLa cells has also revealed that 7-2/MRP resides in the nucleolus and that most of it is associated with complexes sedimenting at approximately 80S, similar to those containing the U3 nucleolar RNA which is known to participate in pre-rRNA processing. These results indicate that the 7-2/MRP ribonucleoparticle may be involved in ribosome biogenesis, in both plant and mammalian cells.     

Structure elucidation of the core octasaccharide from Citrobacter PCM 1487 with the aid of 500-MHz, two-dimensional phase-sensitive correlated, relayed-coherence transfer, double-quantum, triple-quantum filtered, and N.O.E. H-n.m.r. spectra

The main features of the primary structure of the octasaccharide, - -Glcp-(1→2)-- -Glcp-(1→2)-[- -GalpNAc- (1→3)]-- -Galp-(1→3)-- -Glcp-(1→3)-[- -Hepp-(1→7)]-- -Hepp-(1→3)-- -Hep, have been determined in the ab initio manner by ¹H-n.m.r. spectroscopy without resorting to biochemical methods of analysis. Several nontypical interresidue n.O.e. values point to a preferred solution conformation of the molecule.     

Origin of splice junction phosphate in tRNAs processed by HeLa cell extract

Two cloned tRNA genes that contain intervening sequences, yeast tRNA_UCG^Ser and Xenopus laevis tRNA^Tyr, were transcribed in HeLa cell extract. Precursor tRNAs were formed, and were converted to spliced products by a process of excision-ligation. The novel sequences resulting from ligation of tRNA half-molecules were examined by fingerprinting and nearest neighbor analyses. The results indicate that during tRNA splicing in HeLa cell extract, the 3′-terminal phosphate of the 5′ half-molecule is incorporated into a normal 3′,5′-phosphodiester linkage that forms the splice junction. This ligation pathway in HeLa cell extract is distinct from the one described previously in wheat germ extract, which involves formation of 2′-phosphomonoester, 3′,5′-phosphodiester

linkage with the 3′,5′-bond derived from a 5′-terminal phosphate.     

Tumor necrosis factor-alpha converting enzyme is processed by proprotein-convertases to its mature form which is degraded upon phorbol ester stimulation.

Tumor necrosis factor-alpha converting enzyme (TACE or ADAM17) is a member of the ADAM (a disintegrin and metalloproteinase) family of type I membrane proteins and mediates the ectodomain shedding of various membrane-anchored signaling and adhesion proteins. TACE is synthesized as an inactive zymogen, which is subsequently proteolytically processed to the catalytically active form. We have identified the proprotein-convertases PC7 and furin to be involved in maturation of TACE. This maturation is negatively influenced by the phorbol ester phorbol-12-myristate-13-acetate (PMA), which decreases the cellular amount of the mature form of TACE in PMA-treated HEK293 and SH-SY5Y cells. Furthermore, we found that stimulation of protein kinase C or protein kinase A signaling pathways did not influence long-term degradation of mature TACE. Interestingly, PMA treatment of furin-deficient LoVo cells did not affect the degradation of mature TACE. By examination of furin reconstituted LoVo cells we were able to exclude the possibility that PMA modulates furin activity. Moreover, the PMA dependent decrease of the mature enzyme form is specific for TACE, as the amount of mature ADAM10 was unaffected in PMA-treated HEK293 and SH-SY5Y cells. Our results indicate that the activation of TACE by the proprotein-convertases PC7 and furin is very similar to the maturation of ADAM10 although there is a significant difference in the cellular stability of the mature enzyme forms after phorbol ester treatment.     

Studies on the import and processing of the alternative oxidase precursor by isolated soybean mitochondria

Import of the synthetic precursor of the alternative oxidase from soybean was shown to be dependent on a membrane potential and ATP. The membrane potential in soybean mitochondria may be formed either by respiration through the cytochrome pathway, or through the alternative oxidase pathway with NAD⁺-linked substrates. Import of the alternative oxidase precursor in the presence of succinate as respiratory substrate was inhibited by KCN. Import in the presence of malate was insensitive to KCN and SHAM added separately, but was inhibited by KCN and SHAM added together (inhibitors of the cytochrome and alternative oxidases respectively). Import of the alternative oxidase was accompanied by processing of the precursor to a single 32 kDa product in both cotyledon and root mitochondria. This product had a different mobility than the two alternative oxidase bands detected by immunological means (34 and 36 kDa), suggesting that the enzyme had been modified in situ. When the cDNA clone of the alternative oxidase was modified by a single mutation (–2 Arg changed to –2 Gly), the processing of the precursor was inhibited.     

Extreme heterogeneity of polyadenylation sites in mRNAs encoding chloroplast RNA-binding proteins in Nicotiana plumbaginifolia

We have previously characterized nuclear cDNA clones encoding two RNA binding proteins, CP-RBP30 and CP-RBP-31, which are targeted to chloroplasts in Nicotiana plumbaginifolia. In this report we describe the analysis of the 3-untranslated regions (3-UTRs) in 22 CP-RBP30 and 8 CP-RBP31 clones which reveals that mRNAs encoding both proteins have a very complex polyadenylation pattern. Fourteen distinct poly(A) sites were identified among CP-RBP30 clones and four sites among the CP-RBP31 clones. The authenticity of the sites was confirmed by RNase A/T1 mapping of N. plumbaginifolia RNA. CP-RBP30 provides an extreme example of the heterogeneity known to be a feature of mRNA polyadenylation in higher plants. Using PCR we have demonstrated that CP-RBP genes in N. plumbaginifolia and N. sylvestris, in addition to the previously described introns interrupting the coding region, contain an intron located in the 3 non-coding part of the gene. In the case of the CP-RBP31, we have identified one polyadenylation event ocurring in this intron.