An NAD derivative produced during transfer RNA splicing: ADP-ribose 1"-2" cyclic phosphate.

Transfer RNA (tRNA) splicing is essential in Saccharomyces cerevisiae as well as in humans, and many of its features are the same in both. In yeast, the final step of this process is removal of the 2' phosphate generated at the splice junction during ligation. A nicotinamide adenine dinucleotide (NAD)-dependent phosphotransferase catalyzes removal of the 2' phosphate and produces a small molecule. It is shown here that this small molecule is an NAD derivative: adenosine diphosphate (ADP)-ribose 1"-2" cyclic phosphate. Evidence is also presented that this molecule is produced in Xenopus laevis oocytes as a result of dephosphorylation of ligated tRNA.

Gel electrophoretic isolation of splicing complexes containing U1 small nuclear ribonucleoprotein particles.

Assembly of splicing precursor RNAs into ribonucleoprotein particle (RNP) complexes during incubation in in vitro splicing extracts was monitored by a new system of RNP gel electrophoresis. The temporal pattern of assembly observed by our system was identical to that obtained by other gel and gradient methodologies. In contrast to the results obtained by other systems, however, we observed requirements of U1 small nuclear RNPs (snRNPs) and 5' splice junction sequences for formation of specific complexes and retention of U1 snRNPs within gel-fractionated complexes. Single-intron substrate RNAs rapidly assembled into slow-migrating complexes. The first specific complex (A) appeared within a minute of incubation and required ATP, 5' and 3' precursor RNA consensus sequences, and intact U1 and U2 RNAs for formation. A second complex (B) containing precursor RNA appeared after 15 min of incubation. Lariat-exon 2 and exon 1 intermediates first appeared in this complex, operationally defining it as the active spliceosome. U4 RNA was required for appearance of complex B. Released lariat first appeared in a complex of intermediate mobility (A') and subsequently in rapidly migrating diffuse complexes. Ligated product RNA was observed only in fast-migrating complexes. U1 snRNPs were detected as components of gel-isolated complexes. Radiolabeled RNA within the A and B complexes was immunoprecipitated by U1-specific antibodies under gel-loading conditions and from gel-isolated complexes. Therefore, the RNP antigen remained associated with assembled complexes during gel electrophoresis. In addition, 5' splice junction sequences within gel-isolated A and B complexes were inaccessible to RNase H cleavage in the presence of a complementary oligonucleotide. Therefore, nuclear factors that bind 5' splice junctions also remained associated with 5' splice junctions under our gel conditions.

U1 small nuclear ribonucleoproteins are required early during spliceosome assembly.

U1 small nuclear ribonucleoproteins (snRNPs) are required for in vitro splicing of pre-mRNA. Sequences within U1 RNA hybridize to, and thus recognize, 5' splice junctions. We have investigated the mechanism of association of U1 snRNPs with the spliceosome. U1-specific antibodies detected U1 association with precursor RNA early during assembly. Removal of the 5' terminal sequences of U1 RNA by oligo-directed cleavage or removal of U1 snRNPs by immunoprecipitation prior to the addition of precursor RNA depressed the association of all snRNPs with precursor RNA as detected by immunoprecipitation of splicing complexes by either Sm or U1-specific antibodies. Assembly of the spliceosome as monitored by gel electrophoresis was also depressed after cleavage of U1 RNA. The dependency of Sm precipitability of precursor RNA upon the presence of U1 snRNPs suggests that U1 snRNPs participate in the early recognition of substrate RNAs by U2 to U6 snRNPs. Although removal of the 5'-terminal sequences of U1 depressed U1 snRNP association with precursor RNA, it did not eliminate it, suggesting semistable association of U1 snRNPs with the assembling spliceosome in the absence of U1 RNA hybridization. This association was not dependent upon 5' splice junction sequences but was dependent upon 3' intronic sequences, indicating that U1 snRNPs interact with factors recognizing 3' intronic sequences. Mutual dependence of 5' and 3' recognition factors suggests significant snRNP-snRNP communication during early assembly.

Conserved mechanism of tRNA splicing in eukaryotes.

The ligation steps of tRNA splicing in yeast and vertebrate cells have been thought to proceed by fundamentally different mechanisms. Ligation in yeast cells occurs by incorporation of an exogenous phosphate from ATP into the splice junction, with concomitant formation of a 2' phosphate at the 5' junction nucleotide. This phosphate is removed in a subsequent step which, in vitro, is catalyzed by an NAD-dependent dephosphorylating activity. In contrast, tRNA ligation in vertebrates has been reported to occur without incorporation of exogenous phosphate or formation of a 2' phosphate. We demonstrate in this study the existence of a yeast tRNA ligase-like activity in HeLa cells. Furthermore, in extracts from these cells, the entire yeastlike tRNA splicing machinery is intact, including that for cleavage, ligation, and removal of the 2' phosphate in an NAD-dependent fashion to give mature tRNA. These results argue that the mechanism of tRNA splicing is conserved among eukaryotes.

[Ultrasonography studies on spontaneous and pharmacologically modified gallbladder motility]. / Sonographische Untersuchungen zur spontanen und medikamentös beeinflussten Gallenblasenmotilität.

The intra- and interindividual variations of gallbladder motility were sonographically studied in 10 healthy subjects. We investigated the following criteria: a) the gallbladder volumes after overnight fasting on 5 consecutive days, b) the spontaneous motility under fasting over 12 or 24h at hourly intervals, c) the emptying rate and time of maximal contraction after stimulation with sorbitol, and d) the emptying rate and time (like c) after premedication with "cholagogic" drugs (Cholecysmon, Divalol), nifedipine, indomethacin or N-butylscopolaminiumbromide. We found a great intrapersonal and interpersonal variability in gallbladder volumes after overnight fasting in consecutive days. In subjects fasting over 24h phases of dilatation with maxima at 12 AM and 4 PM alternated with phases of contraction with maxima at 8 AM and 4 PM. After premedication with nifedipine, indomethacin and N-butylscopolaminiumbromide a significant decrease of the emptying rate was observed. The time of maximal contraction did not differ however. After premedication we found a distinct intra- and interindividual variability too. Cautious interpretation of gallbladder motility studies is necessary.

In vitro optimization of truncated stem-loop II variants of the hammerhead ribozyme for cleavage in low concentrations of magnesium under non-turnover conditions.

By truncating helix II to two base pairs in a hammerhead ribozyme having long flanking sequences (greater than 30 bases), the rate of cleavage in 1 mM magnesium can be increased roughly 100-fold. Replacing most of the nucleotides in a typical stem-loop II with 1-4 randomized nucleotides gave an RNA library that, even before selection, was more active in 1 mM magnesium than the parent ribozyme, but considerably less active than the truncated stem-loop II ribozyme. A novel, multiround selection for intermolecular cleavage was exploited to optimize this library for cleavage in low concentrations of magnesium. After three rounds of selection at sequentially lower concentrations of magnesium, the library cleaved substrate RNA 20-fold faster than the initial pool and was cloned. This pool was heavily enriched for one particular sequence (5'-CGUG-3') that represented 16 of 52 isolates (the next most common sequence was represented only six times). This sequence also represented the most active sequence, exceeding the activity of the short helix II variant under the conditions of the selection, thereby demonstrating the effectiveness of the selection technique. Analysis of the cleavage rates of RNAs made from eight isolates having different four-base insert sequences allowed assignment of highly preferred bases at each position in the insert. Analysis of pool clones having insert of differing lengths showed that, in general, activity decreased as the length of the insert decreased from 4 to 1. This supports the suggested role of stem-loop II in stabilizing the non-Watson-Crick interactions between the conserved bases of the catalytic core.

HeLa cells contain a 2'-phosphate-specific phosphotransferase similar to a yeast enzyme implicated in tRNA splicing.

We have previously shown that HeLa cells contain activities implicated in tRNA splicing in yeast, a ligase capable of joining tRNA half-molecules and an NAD-dependent activity capable of removing the 2'-phosphate created at the splice junction by the ligase (Zillmann, M., Gorovsky, M.A., and Phizicky, E.M. (1991) Mol. Cell. Biol. 11, 5410-5416). We show here that removal of the splice junction 2'-phosphate is, as in yeast, a 2'-phosphate-specific phosphotransfer reaction that produces the same, as yet unidentified, small molecule. This enzyme is highly specific for oligomeric substrates having internal 2'-phosphates. Oligomers bearing terminal 2'-phosphates are at least 50-fold less reactive and those bearing 5'- or 3'-terminal phosphates are at least 600-fold less reactive. The requirement for an internal 2'-phosphate can be satisfied by a substrate as small as a dimer.

Evidence that a nuclear matrix protein participates in premessenger RNA splicing.

The role of nuclear matrix proteins in premessenger RNA splicing has been investigated using antibodies raised against isolated rat liver nuclear matrix and cross-reactive with a 65-kDa HeLa cell nuclear matrix protein (IGA-65). IGA-65 is an internal nuclear matrix component which can be solubilized as a component of nuclear splicing extracts, by the action of endogenous ribonucleases, EDTA, and DTT during extract preparation. Preincubation of splicing extract with antibodies against IGA-65 (anti-IGA-65) inhibited in vitro splicing of exogenous adenovirus precursor RNA. Furthermore, assembly of precursor RNA into active spliceosome complexes was inhibited by pretreatment of extracts with anti-IGA-65, suggesting a role for IGA-65 during early spliceosome assembly. The IGA-65 present in splicing extracts was distinguishable from known U-snRNP and hnRNP proteins on protein gels. Furthermore, electrophoresis of splicing extract on native gels indicated that IGA-65 was present in protein complexes different from those containing U-snRNPs or hnRNP C protein. The data support identification of complexes containing IGA-65 as nuclear factors involved in pre-mRNA splicing and, by extension, suggest a role for the nuclear matrix during processing in vivo.