Introduction of hidden breaks during rRNA maturation and ageing in Tetrahymena pyriformis

The 23S Ribosomal RNA From Pyrococcus furiosus Is Circularly Permuted

Synthesis and assembly of ribosomal components are fundamental cellular processes and generally well-conserved within the main groups of organisms. Yet, provocative variations to the general schemes exist. We have discovered an unusual processing pathway of pre-rRNA in extreme thermophilic archaea exemplified by Pyrococcus furiosus. The large subunit (LSU) rRNA is produced as a circularly permuted form through circularization followed by excision of Helix 98. As a consequence, the terminal domain VII that comprise the binding site for the signal recognition particle is appended to the 5´ end of the LSU rRNA that instead terminates in Domain VI carrying the Sarcin-Ricin Loop, the primary interaction site with the translational GTPases. To our knowledge, this is the first example of a true post-transcriptional circular permutation of a main functional molecule and the first example of rRNA fragmentation in archaea.

Identification of an Alternative rRNA Post-transcriptional Maturation of 26S rRNA in the Kingdom Fungi

Despite of the integrity of their RNA, some desert truffles present a non-canonical profile of rRNA where 3.3 kb is absent, 1.8 kb is clear and a band of 1.6 kb is observed. A similar rRNA profile was identified in organisms belonging to different life kingdoms, with the exception of the Kingdom Fungi, as a result of a split LSU rRNA called hidden gap. rRNA profiles of desert truffles were analyzed to verify the presence of the non-canonical profile. The RNA of desert truffles and yeast were blotted and hybridized with probes complementary to LSU extremes. RACE of LSU rRNA was carried out to determine the LSU rRNA breakage point. LSU rRNA of desert truffles presents a post-transcriptional cleavage of five nucleotides that generates a hidden gap located in domain D7. LSU splits into two molecules of 1.6 and 1.8 kb. Similar to other organisms, a UAAU tract, downstream of the breakage point, was identified. Phylogenetic comparison suggests that during fungi evolution mutations were introduced in the hypervariable D7 domain, resulting in a sequence that is specifically post-transcriptionally cleaved in some desert truffles.

'Degraded' RNA profiles in Arthropoda and beyond

The requirement for high quality/non-degraded RNA is essential for an array of molecular biology analyses. When analysing the integrity of rRNA from the barnacle Lepas anatifera (Phylum Arthropoda, Subphylum Crustacea), atypical or sub-optimal rRNA profiles that were apparently degraded were observed on a bioanalyser electropherogram. It was subsequently discovered that the rRNA was not degraded, but arose due to a ‘gap deletion’ (also referred to as ‘hidden break’) in the 28S rRNA. An apparent excision at this site caused the 28S rRNA to fragment under heat-denaturing conditions and migrate along with the 18S rRNA, superficially presenting a ‘degraded’ appearance. Examination of the literature showed similar observations in a small number of older studies in insects; however, reading across multiple disciplines suggests that this is a wider issue that occurs across the Animalia and beyond. The current study shows that the 28S rRNA anomaly goes far beyond insects within the Arthropoda and is widespread within this phylum. We confirm that the anomaly is associated with thermal conversion because gap-deletion patterns were observed in heat-denatured samples but not in gels with formaldehyde-denaturing.

Molecular characterization of gap region in 28S rRNA molecules in brine shrimp Artemia parthenogenetica and planarian Dugesia japonica

In most insects and some other protostomes, a small stretch of nucleotides can be removed from mature 28S rRNA molecules, which could create two 28S rRNA subunits (28Sα and 28Sβ). Thus, during electrophoresis, the rRNA profiles of these organisms may differ significantly from the standard benchmark since the two subunits co-migrate with the 18S rRNA. To understand the structure and mechanism of the atypical 28S rRNA molecule, partial fragments of 28Sα and 28Sβ in brine shrimp Artemia parthenogenetica and planarian Dugesia japonica were cloned using a modified technology based on terminal transferase. Alignment with the corresponding sequences of 28S rDNAs indicates that there are 41 nucleotides in A. parthenogenetica and 42 nucleotides in D. japonica absent from the mature rRNAs. The AU content of the gap sequences of D. japonica and A. parthenogenetica is high. Both the gaps may form stem-loop structure. In D. japonica a UAAU cleavage signal is identified in the loop, but it is absent in A. parthenogenetica. Thus, it is proposed that the gap processing of 28S rRNA was a late enzyme-dependent cleavage event in the rRNA maturational process based on the AU rich gap sequence and the formation of the stem-loop structure to expose the processing segment, while the deletion of the gap region would not affect the structure and function of the 28S rRNA molecule.

A characterization of Tetrahymena mRNA by in vitro translation: The effects of culture growth on the recruitment of poly (A)(+) and poly (A)(-) RNA

Messenger RNA was extracted from exponentially growing and from stationary cultures of Tetrahymena thermophila. It was separated into polyadenylated and non-polyadenylated fractions which were used as templates in a rabbit reticulocyte protein synthesizing system. The translated proteins were analysed by one and by two dimensional electrophoresis. Our experiments were intended to answer the question to which extent the abundance and the specificity of mRNA facilitates or accompanies the passage of cells through one culture growth cycle. As illustrated by the identification of 113 proteins very few differences between translated messages accompany the transition to the stationary phase, the most obvious feature being a change in the intracellular location of translation activities. These data are discussed with special reference to the prevailing occupation of Tetrahymena which is biomass production.

Novel processing in a mammalian nuclear 28S pre-rRNA: tissue-specific elimination of an 'intron' bearing a hidden break site

Splitting and apparent splicing of ribosomal RNA, both previously unknown in vertebrates, were found in rodents of the genus Ctenomys. Instead of being formed by a single molecule of 4.4 kb, 28S rRNA is split in two molecules of 2.6 and 1.8 kb. A hidden break, mapping within a 106 bp 'intron' located in the D6 divergent region, is expressed in mature ribosomes of liver, lung, heart and spleen, as well as in primary fibroblast cultures. Testis-specific processing eliminates the intron and concomitantly the break site, producing non-split 28S rRNA molecules exclusively in this organ. The intron is flanked by two 9 bp direct repeats, revealing the acquisition by insertion of a novel rRNA processing strategy in the evolution of higher organisms.

Linker histone H1 regulates specific gene expression but not global transcription in vivo

In a linker histone H1 knockout strain (delta H1) of Tetrahymena thermophila, the number of mature RNAs produced by genes transcribed by pol I and pol III and of most genes transcribed by pol II remains unchanged. However, H1 is required for the normal basal repression of a gene (ngoA) in growing cells but is not required for its activated expression in starved cells. Surprisingly, H1 is required for the activated expression of another gene (CyP) in starved cells but not for its repression in growing cells. Thus, H1 does not have a major effect on global transcription but can act as either a positive or negative gene-specific regulator of transcription in vivo.

The identification and characterization of a break within the large subunit ribosomal RNA of Trichinella spiralis: comparison of gap sequences within the genus

A break was identified in the large subunit ribosomal RNA of Trichinella spiralis that results in its dissociation into 2 smaller fragments of approximately equal length. The approximate location of the break within the encoding gene was mapped from subcloned rDNA fragments by S1 protection experiments. The boundaries of the break were determined by cDNA primer extension and S1 nuclease protection assays. The excised fragment (gap sequence) was localized to expansion segment 5 within domain IV from which 86 bases are removed during the excision process. The gap region is flanked by the consensus sequence CGAAAG; however, comparison of expansion segment 5 sequences from T. spiralis, T. nativa, T. nelsoni and T. pseudospiralis, all of which undergo 'gap processing', demonstrates significant size and sequence heterogeneity and provides little evidence for additional consensus sequences which could be implicated in gap processing.

Characterization of a 54-nucleotide gap region in the 28S rRNA gene of Schistosoma mansoni

We have analyzed 572 bp in the 28S rDNA of the human blood fluke Schistosoma mansoni which correspond to expansion segment 5 of domain IV as defined by Clark et al. for the Xenopus laevis 28S rRNA. S1 nuclease mapping and primer extension analysis comparing this region with the mature 28S rRNA indicate that there are 54 nucleotides present in the 28S rDNA which are absent from the mature rRNA. This defines a gap that creates two 28S rRNA subunits (28S alpha and 28S beta). Comparison of the S. mansoni sequence with rDNAs of other organisms which contain gaps in their 28S rRNA shows that the overall features are conserved except that the S. mansoni gap is less A + T-rich. The conserved features include: (1) the location of the gap within the 28S rRNA; (2) the predicted secondary structure of the gap, containing a stem-loop with a UAAU sequence within the loop; and (3) a conserved CGAAAGGG on the 3' side of the gap.

Complete sequence of the extrachromosomal rDNA molecule from the ciliate Tetrahymena thermophila strain B1868VII

The recent development of rDNA vectors for transformation of Tetrahymena combined with improved microinjection technology should lead to a renewed interest in this organism. In particular, the rDNA itself constitutes an attractive system for biochemical studies. The rDNA is amplified to a level of 2% of the total DNA and exists as extrachromosomal molecules. Furthermore, the rDNA is homogeneous in sequence because it is derived from a single gene during sexual reorganization. In order to facilitate studies of this molecule, we report here a compilation of previously published sequence information together with new sequence data that completes the entire sequence of the 21 kb rDNA molecule.

Comparison of primary and secondary 26S rRNA structures in two Tetrahymena species: evidence for a strong evolutionary and structural constraint in expansion segments

We have determined the nucleotide sequence of the 26S large subunit (LSU) rRNA genes for two Tetrahymena species, T. thermophila and T. pyriformis. The inferred rRNA sequences are presented in their most probable secondary structures based on compensatory mutations, energy, and conservation criteria. The majority of the nucleotide changes between the two Tetrahymena LSU rRNAs and the positions of a relatively large deletion and of the processing cleavage sites resulting in the generation of the hidden break are all located within the so-called divergent domains or expansion segments. These are regions within the common core of secondary structure where expansions have taken place during the evolution of the rRNA of higher eukaryotes. The dispensable nature of some of the expansion segments has been taken as evidence of their non-functionality. However, our data show that a considerable selective constraint has operated to preserve the secondary structure of these segments. Especially in the case of the D2 and D8 segments, the presence of a considerable number of compensatory base changes suggests that the secondary structure of these regions is of functional importance. Alternatively, these expansion segments may have maintained characteristic folding patterns because only such structures are being tolerated within otherwise functionally important regions.

Cloning of Tetrahymena genomic sequences whose message abundance is increased during conjugation

A molecular and biochemical inquiry into protein regulation during Tetrahymena thermophila conjugation was carried out in two ways: a two-dimensional gel analysis of newly translated proteins and the molecular cloning of genes whose message abundance is increased. The two-dimensional gel analysis indicated that the synthesis of 32 predominantly basic proteins was stimulated in conjugating cells. The induction of these proteins could not be correlated with length of starvation or with mating type. The transcription pattern and molecular organization of three clones of T. thermophila genomic DNA, selected on the basis of differential hybridization to conjugating or control cell RNA, were investigated. Two of the clones, which were homologous to transcripts detected in conjugating cells, showed no rearrangements between micro- and macronuclear DNA. A third clone was divided into three segments. One segment was homologous to sequences limited to the micronucleus. A second segment hybridized to a large number of restriction fragments of micronuclear DNA digested with HindIII but to only two fragments of macronuclear DNA. A third segment, which was complementary to one transcript in conjugating cells and to two different transcripts in control cells, hybridized to two fragments in micronuclear DNA and one fragment in macronuclear DNA.

A method for isolation of nuclei containing undegraded RNA from RNAase-rich plasmodia of Physarum polycephalum

(1) In order to protect the nuclear RNA of Physarum polycephalum plasmodia during cell homogenisation and purification of the nuclei, the following conditions were used: low temperature (-11 degrees C), high pH (8.1-8.9), formaldehyde (2.8%) and spermine (2.3 mM). (2) The efficiency of these RNAase-inhibiting and inactivating conditions is demonstrated by the high molecular weight of the processing products of transcripts from ribosomal genes (11.9, 9.5 and 5.0 kilobases), which were recovered from the isolated nuclei and visualised on agarose gels. (3) Hybridisation experiments with a DNA probe from an actin gene on size-fractionated nuclear RNA (Northern blots) indicate that the transcripts from actin genes are rapidly spliced in P. polycephalum. (4) The nuclear polyadenylated RNA has an average size of about 2.2 kb, which is not significantly larger than the average length of mRNA.

Precise identification of cleavage sites involved in the unusual processing of trypanosome ribosomal RNA

The large subunit ribosomal RNA (LSRNA) of Trypanosoma brucei is unusual in being cleaved at multiple sites to yield six stable fragments of RNA. We report here the complete nucleotide sequence of two regions of the ribosomal DNA repeat unit. The first sequence includes all of the processing sites involved in the generation of one of the small LSRNA fragments. The second region encodes the trypanosome 5.8 S RNA. By RNA sequencing and S1 nuclease mapping, we have identified the processing sites involved in the generation of both of these small RNAs. On the basis of predicted secondary structure models, we infer that all the cleavages apparently occur near the junction of single- and double-stranded regions. The sites involved in the novel LSRNA processing show a clear symmetry with respect to a conserved region of ten base-pairs. No such signals are evident for the processing sites that generate the 5.8 S RNA.

Characterization of RNA from Leishmania tropica and Leishmania d.donovani promastigotes

RNA has been prepared from promastigotes of Leishmania tropica and Leishmania d.donovani using three different methods. Extraction by hot phenol/isothiocyanate gave the best quantitative and qualitative results. The analysis of total RNA on methyl mercuric agarose gels shows that the large rRNA species is nicked: it is composed of a 630 and a 560 kDa molecule. The small rRNA species has a molecular weight of 800,000. Poly(A+) RNA can be translated in a rabbit reticulocyte lysate system. The newly synthesized products comprise high molecular weight proteins and show different patterns using RNA from L. tropica or from L. d. donovani promastigotes.

Characterization of an authentic intermediate in the self-splicing process of ribosomal precursor RNA in macronuclei of Tetrahymena thermophila

We have characterized a 1.5 kb RNA species in T. thermophila macronuclei previously found in vivo and including intron sequences linked to the 3' exon. This IVS-3' exon RNA could be detected in gels as a discrete molecule only after denaturation of nuclear RNA. After addition of 32P-GTP, as splicing cofactor in a nuclear in vitro system, the IVS-3' exon RNA was labeled at its 5' terminus, as was the by-product of splicing, the excised IVS RNA. The time course of labeling indicates that the IVS-3' exon RNA acts like a reaction intermediate and specifically a kinetic precursor to IVS RNA. Partial nuclease digestions showed that the IVS-3' exon RNA and the IVS RNA have the same 5' terminal sequence. In addition the IVS-3' exon RNA can release the 15-mer oligonucleotide cleaved off during circularization of IVS RNA under conditions of high temperature. Taken together, the structural, functional, and kinetic properties of the IVS-3' exon RNA strongly suggest that it represents a previously postulated in vivo intermediate in the splicing pathway.

A germ line specific DNA sequence is transcribed in Tetrahymena

In the ciliated protozoan Tetrahymena 10-20% of the DNA sequences are micronucleus (germ line) specific. Six members of a family of repeated mic-specific DNA sequences are homologous to a 1.5-kb poly(A)+ RNA. The transcript is present in mature cells starved in 10 or 60 mM Tris, in starved immature cells, and in stationary cells. RNA from log-phase and heat-shocked cells does not have detectable levels of the transcript. These data indicate that at least one germ line limited DNA sequence is transcribed in the micronucleus of Tetrahymena.

Unexpectedly long 14S ribosomal RNA gene in Tetrahymena mitochondria

Extraction of RNA from Tetrahymena mitochondrial ribosomes yields several RNA species, including a "large" 21S molecule, a "small" 14S molecule, a 7S molecule, and other smaller RNAs. The molecular weight of the 14S rRNA indicates that it is about 1,300 bases in length. We have sequenced the 14S rRNA gene and, by aligning our sequence with that of the corresponding small rRNA from E. coli, find that the 14S rDNA is at least 1,635 bases in length. We propose, based on the results of hybridization studies, that this unexpected length is due to the presence of 7S RNA sequence within the 14S gene sequence. The 7S region is apparently lost from the 14S rRNA, yet is still a component of the ribosome.

Phosphorylation of a 40S ribosomal subunit protein in Tetrahymena. Lack of correlation with cellular growth and ribosome stability

In Tetrahymena the small ribosomal subunit protein S7, which appears to be the equivalent of S6 of higher eukaryotes, undergoes reversible phosphorylation under a set of defined conditions. In an attempt to understand the physiological role of such reversible phosphorylation, we examined the status of ribosomal protein S7 in growing cells and growth-arrested cells, starving either non-specifically for nutrients or specifically for a single essential amino acid. These experiments allowed us to dissociate S7 phosphorylation from changes in the translational activity and the stability of ribosomes. The results revealed complete lack of correlation between phosphorylation of S7 and both the growth status of the cells and the in vivo stability of ribosomes. Taken together with the observation that phosphorylation of S7 occurs only when the cells are starved in buffers containing sodium chloride or high concentrations of Tris, non-essential ions for normal growth, our data suggest that this protein modification is required to maintain the functional integrity of the ribosomes in an altered electrostatic environment, induced by changes in the extracellular ionic conditions.

Three small RNAs within the 10 kb trypanosome rRNA transcription unit are analogous to domain VII of other eukaryotic 28S rRNAs

We have localized the six ribosomal RNAs (rRNAs) which encode the 28S rRNA region of Trypanosoma brucei. These six rRNAs include two large rRNAs, 28S alpha (approx. 1840 nt) and 28S beta (approx. 1570 nt), and four small rRNAs of approximate sizes 220, 180, 140 and 70 nt. Three of these four small rRNAs (180, 70 and 140) are found at the 3' end of the 28S rRNAs region. Sequence analysis of this area shows that these three small rRNAs encode Domain VII, the last domain of secondary structure in the 28S rRNAs of eukaryotes. Hybridization of labeled nascent RNA to the cloned repeat unit and S1 nuclease protection analysis of putative precursors show that transcription initiates approximately 1.2 kb upstream of the 18S rRNA and terminates after the last small rRNA (140) at the 3' end of the 28S rRNA region. Analysis of three putative rRNA precursors suggests that the small rRNAs are not processed from the primary transcript until after the usual processing of the 5.8S rRNA region.

Nucleotide sequence of the 5S ribosomal RNA gene repeat of Trypanosoma brucei

The 750 base pair tandem repeat specifying the 5S ribosomal RNA of Trypanosoma brucei brucei has been cloned and four independent clones sequenced to completion. The repeat specifies only a single 5S rRNA and is unusually long when compared with other 5S gene repeats. The sequenced copies contain a number of sequence polymorphisms similar to those seen in the ribosomal genes of other organisms. By comparison with the consensus sequence for RNA polymerase III promoters ('internal control regions') a possible 'internal control region' for RNA polymerase III can be located in the predicted position within the 5S ribosomal RNA sequence.

rRNA processing: removal of only nineteen bases at the gap between 28S alpha and 28S beta rRNAs in Sciara coprophila

We have determined the sequence of the rDNA region between the 28S alpha and 28S beta rRNA coding segments (termed a "gap") in the insect Sciara coprophila, and have used S1 nuclease mapping and cDNA primer extension to define the 5' and 3' boundaries of the gap. Only 19 bases found in rDNA at the gap region are absent from mature 28S rRNA. Eukaryotic rRNAs contain stretches of nucleotides ("expansion segments") which are absent in E. coli rRNA. The gap region in Sciara is located within expansion segment V. Therefore, the excision of 19 bases in the Sciara gap suggests that a large portion of expansion segment V plays no function in mature ribosomes. Specific sequences conserved in Sciara and Drosophila are considered as candidates for recognition signals for the excision of the gap transcript.

Starved Tetrahymena thermophila cells that are unable to mount an effective heat shock response selectively degrade their rRNA

Tetrahymena thermophila cells that had been shifted from log growth to a non-nutrient medium (60 mM Tris) were unable, during the first few hours of starvation, to mount a successful heat shock response and were killed by what should normally have been a nonlethal heat shock. An examination of the protein synthetic response of these short-starved cells during heat shock revealed that whereas they were able to initiate the synthesis of heat shock proteins, it was at a much reduced rate relative to controls and they quickly lost all capacity to synthesize any proteins. Certain pretreatments of cells, including a prior heat shock, abolished the heat shock inviability of these starved cells. Also, if cells were transferred to 10 mM Tris rather than 60 mM Tris, they were not killed by the same heat treatment. We found no abnormalities in either heat shock or non-heat shock mRNA metabolism in starved cells unable to survive a sublethal heat shock when compared with the response of those cells which can survive such a treatment. However, selective rRNA degradation occurred in the nonsurviving cells during the heat shock and this presumably accounted for their inviability. A prior heat shock administered to growing cells not only immunized them against the lethality of a heat shock while starved, but also prevented rRNA degradation from occurring.

Starved Tetrahymena thermophila cells that are unable to mount an effective heat shock response selectively degrade their rRNA

Tetrahymena thermophila cells that had been shifted from log growth to a non-nutrient medium (60 mM Tris) were unable, during the first few hours of starvation, to mount a successful heat shock response and were killed by what should normally have been a nonlethal heat shock. An examination of the protein synthetic response of these short-starved cells during heat shock revealed that whereas they were able to initiate the synthesis of heat shock proteins, it was at a much reduced rate relative to controls and they quickly lost all capacity to synthesize any proteins. Certain pretreatments of cells, including a prior heat shock, abolished the heat shock inviability of these starved cells. Also, if cells were transferred to 10 mM Tris rather than 60 mM Tris, they were not killed by the same heat treatment. We found no abnormalities in either heat shock or non-heat shock mRNA metabolism in starved cells unable to survive a sublethal heat shock when compared with the response of those cells which can survive such a treatment. However, selective rRNA degradation occurred in the nonsurviving cells during the heat shock and this presumably accounted for their inviability. A prior heat shock administered to growing cells not only immunized them against the lethality of a heat shock while starved, but also prevented rRNA degradation from occurring.

Thermal down-regulation of exportable rRNA in nuclei

The export of rRNP particles from nuclei isolated from Tetrahymena was investigated after preincubating the nuclei at different temperatures under nonpermissive export-conditions. We observed a new phenomenon: Temperature elevation from the sublethal cells' growth temperature, 8 degrees C, to the optimal temperature, 28 degrees C, lead to a gradual down-regulation in the maximal proportion of rRNP particles subsequently exported from nuclei at 28 degrees C. This thermal down-regulation is apparently not due to qualitative changes in the exported rRNP particles, a derangement in the gross nuclear organization, a degradation and/or nicking of the nuclear rRNA, a gross decomposition of the major nuclear proteins, a random cross-linking of nuclear components by disulfide bonds, or an elution of nuclear factors possibly required for rRNP export. Moreover, there is a corresponding thermal down-regulation in nuclear envelope-free nuclei. Our data indicate that nuclei possess a mechanism that regulates the number of potentially exportable rRNP particles at a level preceding the rRNP passage through the nuclear envelope.

Response of Tetrahymena pyriformis to stress induced by starvation

mRNA synthesis was studied in exponentially growing and starved Tetrahymena pyriformis. Poly(A)-containing RNAs separated from total RNA by affinity chromatography on oligo(dT)-cellulose were characterized by poly acrylamide gel electrophoresis; their template activity was assayed in a rabbit reticulocyte lysate system and their translation products were analysed using two-dimensional electrophoresis according to O'Farrell. Polysome profiles show that the bulk of ribosomes are in 80S monosomes in starved cells, whereas less than 8% are present in the form of monosomes in exponentially growing cells, the rest being engaged in polysomes. Polysomes are almost completely reformed 30 min after addition of enriched medium to suspensions of starved cells. This polysome reformation is dependent on mRNA synthesis since we have shown that it is inhibited by actinomycin D. Electrophoretic profiles of poly(A)-rich RNA isolated from cytoplasmic fractions of exponential and starved cells are indistinguishable except that in the latter state significant amounts of low-molecular-mass species are observed. Poly(A)-rich RNAs isolated from polysomal and non-polysomal (subpolysomal) fractions of exponential cells are equally able to promote protein synthesis. The corresponding poly(A)-rich RNAs isolated from starved cells also possess equal template activities which are, however, 15% lower than those of the poly(A)-rich RNAs of exponentially growing cells. We also present evidence that in the system used in vitro, polyadenylated RNA isolated from heavy polysomes of starved cells directs the synthesis of four sets of proteins with molecular masses around 100 kDa, 70 kDa, 50 kDa and 30 kDa. The former two groups of proteins are more abundant in the translation products of poly(A)-rich RNA of starved than of normal cells, whereas the latter two groups are present only in the translation products of poly(A)-rich RNA of starved Cells. The fluorograms of the translation products obtained in vitro from subpolysomal poly(A)-rich RNA are identical to those obtained from polysomal poly(A)-rich RNA. Studies on starved cells in vivo show that polypeptides of 100 kDa, 70 kDa and 38 kDa are more strongly labelled and also revealed the specific presence of 85 kDa, 55 kDa, 50 kDa and 25 kDa proteins. These results lead us to the conclusion that this microorganism responds to depleted environmental conditions by regulating gene expression at the transcriptional level, but also at the translational level.

Small-size ribosomal RNA species in Trypanosoma cruzi

Trypanosoma cruzi ribosomal RNA was analyzed electrophoresis. On agarose gels, where both large- and small-size species are grossly fractionable, it revealed two bands in the small-size region. These were similar in size to the mammalian 5.8 S and 5 S species. Increased resolution, however, showed these two bands to be composite. The pseudo 5.8 S band contained three, and the pseudo 5 S two, discretely sized molecules. The ribosomal binding of four of these five novel species is apparently dependent on large ribosomal subunit proteins. One species is hydrogen bonded to the beta species of 24 S ribosomal RNA. The five species were estimated to be 261, 217, 197, 141 and 110 nucleotides long.

Hidden breaks in ribosomal RNA of phylogenetically tetraploid fish and their possible role in the diploidization process

Hidden breaks occur in the ribosomal RNA of tetraploid Cyprinid fish such that the large ribosomal RNA (28 S) yields upon denaturation two RNA fragments of 8.7 X 10(5) and 5.0 X 10(5) daltons, whereas the small rRNA (18 S) yields fragments of 3.2 X 10(5) to 5.0 X 10(4) daltons. In tetraploid Cyprinids hidden breaks occur only in the rRNA of somatic tissue and not in oocytes and sperm cells. Hidden breaks can be detected only slightly in diploid Cyprinid species. Ribosomes purified from somatic tissue of tetraploid Cyprinids show a reduced efficiency in protein synthesis in vitro. The ribosomal proteins from diploid and tetraploid Cyprinid fish show considerable electrophoretic differences. This is discussed in light of a possible functional role of hidden breaks in rRNA in the process of diploidization of gene expression in tetraploid Cyprinid species.

In vitro nuclear transport of ribosomal ribonucleoprotein: temperature affects quantity but not quality of exported particles

The in vitro export of ribosomal ribonucleoprotein (rRNP) from Tetrahymena nuclei was investigated at the optimal growth temperature of 28 degrees C and at the nonlethal temperature of 8 degrees C. At both temperatures, nuclei exported ribosomal precursor particles that revealed the same physical qualities of size, appearance in negative-staining electron microscopy, sedimentation coefficient, buoyant density, and rRNA pattern. Surprisingly, fewer rRNP particles were exported at 8 than at 28 degrees C, as was revealed by a lower saturation plateau in the export kinetics from nuclei prelabeled with [3H]uridine. Upon a temperature increase from 8 to 28 degrees C, additional rRNP particles were exported. We conclude that nuclei export only a defined portion of rRNP particles at a given temperature, although enough potentially transportable rRNP particles are present in nuclei. Obviously, the reactivity of at least one of the reactants involved directly or indirectly in rRNP export changes with temperature.

Complex endonucleolytic cleavage pattern during early events in the processing of pre-rRNA in the lower eukaryote, Tetrahymena thermophila

We have analysed nuclear RNA from T. thermophila by RNA transfer hybridization using cloned rDNA fragments. A very high number of in vivo intermediates and by-products of rRNA processing were identified. These include putative intermediates of the splicing process and alternative products resulting from temporal variability in various endonucleolytic cleavages. In addition, four small RNA species including only transcribed spacer sequences were detected. These are (1) the IVS RNA (approximately 400 bases), the by-product of the splicing process, (2) a fragment from the internal transcribed spacer (approximately 360 bases), possibly resulting from 3'-end processing of pre-17S rRNA, (3) a fragment comprising most or all of the external transcribed spacer (approximately 600 bases) obviously representing the major by-product of 5'-end processing, and, in addition, (4) a small fragment from the initiation region (approximately 230 bases) which might be a product of premature transcription termination.

Concerning the thermal stability of E. coli 23S ribosomal RNA

Total RNA prepared from E. coli by several extraction procedures behaves as a mixture of covalently continuous heat stable 23S, 16S and 4-5S components. 16S rRNA remains heat stable after isolation from such preparations, whereas isolated 23S rRNA is heat labile but becomes heat stable after EDTA treatment. This and other evidence leads to the conclusion that heat lability of purified 23S rRNA is due, not to nuclease contamination of the type observed in earlier studies of the stability of this RNA, but to polyvalent cation catalyzed temperature-dependent scission of phosphodiester bonds. Heat stability of 23S rRNA in total RNA is due to the presence in these preparations of a contaminant which appears to act as a chelator of polyvalent cations. This material is similar or identical to the pyrogenic E. coli lipopolysaccharide described by Westphal and coll.

Fate of an intervening sequence ribonucleic acid: excision and cyclization of the Tetrahymena ribosomal ribonucleic acid intervening sequence in vivo

In previous studies of RNA splicing in vitro, we have shown that the intervening sequence (IVS) of the Tetrahymena rRNA precursor is excised as a unique linear RNA molecule and subsequently cyclized. In the present work, we have investigated the occurrence and stability of these RNA species in vivo. RNA was separated by gel electrophoresis, transferred to diazotized paper, and hybridized with 32P-labeled DNA probes. RNA molecules containing the IVS were found to reside within the nucleus and not in the cytoplasm. The species found in nucleus include both the linear and circular forms of the excised IVS RNA, as well as the unspliced precursor. On the basis of quantitation of the hybridization, the half-lives of the IVS-containing pre-rRNA and the excised IVS RNA in rapidly growing cells were estimated as 2 and 6 s, respectively. We conclude that splicing is not a rate-limiting step in rRNA maturation and that the IVS RNA is quickly degraded after its excision. When the deproteinized nuclear RNA was incubated at 37 degrees C in a Mg2+-containing solution, a substantial portion of the linear IVS RNA was converted to the circular form. Autocyclization, previously characterized with IVS RNA produced by splicing in vitro, is therefore also a property of IVS RNA produced in vivo.

In vitro nuclear transport of ribosomal ribonucleoprotein: temperature affects quantity but not quality of exported particles

The in vitro export of ribosomal ribonucleoprotein (rRNP) from Tetrahymena nuclei was investigated at the optimal growth temperature of 28 degrees C and at the nonlethal temperature of 8 degrees C. At both temperatures, nuclei exported ribosomal precursor particles that revealed the same physical qualities of size, appearance in negative-staining electron microscopy, sedimentation coefficient, buoyant density, and rRNA pattern. Surprisingly, fewer rRNP particles were exported at 8 than at 28 degrees C, as was revealed by a lower saturation plateau in the export kinetics from nuclei prelabeled with [3H]uridine. Upon a temperature increase from 8 to 28 degrees C, additional rRNP particles were exported. We conclude that nuclei export only a defined portion of rRNP particles at a given temperature, although enough potentially transportable rRNP particles are present in nuclei. Obviously, the reactivity of at least one of the reactants involved directly or indirectly in rRNP export changes with temperature.

Protein synthesis directed by polyadenylated and non-polyadenylated RNA isolated from membrane-bound and free polysomes of Tetrahymena pyriformis

Free and membrane-bound polysomes were prepared from the protozoa Tetrahymena pyriformis using a procedure which gives good recovery and practically no cross-contamination. Polysomes are intact as analysed by sedimentation analysis. Poly(A)-rich RNA and poly(A)-free RNA, isolated from both populations of polysomes, show similar electrophoretic patterns. These RNAs were translated in the rabbit reticulocyte lysate cell-free system and the translation products were analysed by one-dimensional and two-dimensional gel electrophoresis. The most striking differences were found in the two-dimensional electrophoretic analysis namely: (a) a group of polypeptides (10) is synthesized mainly on membrane-bound polysomes, (b) a second abundant group is synthesized mainly in free polysomes (c) and a third class of polypeptides is synthesized on both kinds of polysomes. Poly(A)-free RNAs, isolated from free polysomes, are also able to promote synthesis of some polypeptides. The results are discussed taking into account the fact that T. pyriformis is a non-secretory cell.

Determination of the transcription initiation site of Tetrahymena pyriformis rDNA using in vitro capping of 35S pre-rRNA

Approximately 700 nucleotide sequences surrounding the transcription initiation site were determined with a cloned rDNA fragment of Tetrahymena pyriformis and the transcription initiation site was localized on these sequences using purified 35S pre-rRNA. A considerable portion of the 35S pre-rRNA was found to be capped in vitro. The 32P-labeled, capped 35S pre-rRNA, on nucleus P1 protection mapping, gave the protection band which is identical in size with that obtained with bulk 35S pre-rRNA. Both reverse transcription extension and nuclease P1 mapping localized the 5'-end of the 35S pre-rRNA at the same adenine nucleotide, 496 base pairs upstream from the HindIII site of the cloned rDNA fragment. Furthermore, sequencing of the 5'-terminal region of the in vitro capped 35S pre-rRNA unambiguously confirmed the above result. The strategy adopted in the present experiment could serve as a general procedure for determining the transcription initiation point even in cases where the concentration of the primary transcript is low.

The nucleotide sequence at the transcription termination site of the ribosomal RNA gene in Tetrahymena thermophila

The sequence of 415 nucleotides surrounding the transcription termination site for ribosomal RNA in Tetrahymena thermophila has been determined. The positions of the 3'-ends of mature 26S rRNA, pre-26S rRNA and 35S pre-rRNA were localized within this sequence by hybridization of the purified RNA species to be selected DNA fragments, followed by S1 nuclease treatment of the hybrid and a precise sizing of the RNA-protected DNA fragments on sequencing gels. The 35S pre-rRNA population contained molecules with two distinct 3'-ends, one of which is identical to the end of pre-26S and 26S rRNA, while the other corresponds to a position 15 nucleotides further downstream, which is assumed to be the transcription termination site. The non-coding DNA strand contains a cluster of T's at the putative termination site, and several other T clusters are found further downstream. A short inverted repeat sequence is located near the putative termination site within the transcribed region. The possible role of these structures for transcription termination is discussed.

Localization of putative transcription initiation site on the cloned rDNA fragment of Tetrahymena pyriformis

A DNA fragment (1.4 Kb) which codes for 5' region of 35S ribosomal precursor RNA (pre-rRNA) in Tetrahymena pyriformis was cloned with pBR322. The fragment was cleaved from the central part of the palindromic rDNA with restriction endonuclease KpnI and HindIII, and ligated to the larger moiety of pBR322 DNA-HindIII-BamHI fragment together with lambda DNA-KpnI-BamHI fragment through trimolecular ligation. The analysis of R-loop formed between KpnI-linearized recombinant plasmid and 35S pre-rRNA revealed a DNA:RNA hybrid region of 465 +/- 30 base pairs in length. Considering the contraction of DNA:RNA hybrids relative to DNA duplexes (Philippsen et al., J. Mol. Biol., 123, 387-404, 1978), the size of the hybrid region was corrected to about 490 base pairs. Alternatively, the size of DNA which was protected against nuclease S1 due to hybrid formation with 35S pre-rRNA was estimated to be 490 nucleotides long. These data indicate that the transcription initiation site is localized at about 490 base pairs from the HindIII site of the cloned rDNA fragment.

An electron microscopic analysis of transcription of nucleolar chromatin isolated from Tetrahymena pyriformis

Transcriptionally active nucleoli and solubilized nucleolar chromatin were visualized by electron microscopy. The palindromic structure of the chromatin was demonstrated by spreading the chromatin on glow-discharged grids. In the presence of single-strand binding EcoHDP protein the preribosomal RNA transcripts are seen attached to the RNA-polymerase molecules in the electron micrographs. Each palindrome contains two preribosomal RNA genes. THe strict termination properties of the transcription are indicated by the absence of transcriptional complexes in the distal parts of the molecules. - Investigation of the process of transcription in nucleolar chromatin being depleted of a termination protein by ammonium sulfate-treatment showed in agreement with biochemical studies that only some of the RNA polymerases terminate properly while other transcribe into the distal spacer region. The elongation rate is estimated to be slightly lower than in the gene region. The results are discussed in relation to biochemical studies of the transcriptional properties of the chromatin.

A nucleolar skeleton of protein filaments demonstrated in amplified nucleoli of Xenopus laevis

The amplified, extrachromosomal nucleoli of Xenopus oocytes contain a meshwork of approximately 4-nm-thick filaments, which are densely coiled into higher-order fibrils of diameter 30-40 nm and are resistant to treatment with high- and low-salt concentrations, nucleases (DNase I, pancreatic RNase, micrococcal nuclease), sulfhydryl agents, and various nonionic detergents. This filamentous "skeleton" has been prepared from manually isolated nuclear contents and nucleoli as well as from nucleoli isolated by fluorescence-activated particle sorting. The nucleolar skeletons are observed in light and electron microscopy and are characterized by ravels of filaments that are especially densely packed in the nucleolar cortex. DNA as well as RNA are not constituents of this structure, and precursors to ribosomal RNAs are completely removed from the extraction-resistant filaments by treatment with high-salt buffer or RNase. Fractions of isolated nucleolar skeletons show specific enrichment of an acidic major protein of 145,000 mol wt and an apparent pI value of approximately 6.15, accompanied in some preparations by various amounts of minor proteins. The demonstration of this skeletal structure in "free" extrachromosomal nucleoli excludes the problem of contaminations by nonnucleolar material such as perinucleolar heterochromatin normally encountered in studies of nucleoli from somatic cells. It is suggested that this insoluble protein filament complex forms a skeleton specific to the nucleolus proper that is different from other extraction-resistant components of the nucleus such as matrix and lamina and is involved in the spatial organization of the nucleolar chromatin and its transcriptional products.

Replication of the extrachromosomal ribosomal RNA genes of Tetrahymena thermophilia

Cultures of Tetrahymena thermophila were deprived of nutrients and later refed with enriched medium to obtain partial synchrony of DNA replication. Preferential replication of the extrachromosomal, macronuclear ribosomal RNA genes (rDNA) was found to occur at 40-80 min after refeeding. The rDNA accounted for one half of the label incorporated into cellular DNA during this period. Electron microscopy of the purified rDNA showed 1% replicative intermediates. Their structure was that expected for bidirectional replication of the linear rDNA from an origin or origins located in the central nontranscribed region of the palindromic molecule. Similar forms had previously been observed for the rDNA of a related species, Tetrahymena pyriformis. The electron microscopic data was consistent with an origin of replication located approximatley 600 base pairs from the center of the rDNA of T. thermophila, in contrast to a more central location in the rDNA of T. pyriformis. One implication of an off-center origin of replication is that there are two such sequences per palindromic molecule.

Processing of the ribonucleic acid in the large ribosomal subunits of Urechis caupo

Ribosomal subunits were isolated from eggs or embryos of Urechis caupo, and the ribonucleic acid (RNA) was characterized by electrophoresis under denaturing conditions. The small ribosomal subunit contains a single 17S RNA sequence with a molecular weight of 6.20 X 10(5). The large ribosomal subunit contains four polynucleotide sequences. The 5S RNA has a molecular weight of 4.09 X 10(4). The 26S RNA complex isolated under nondenaturing conditions dissociates in the presence of formamide to yield a 5.8S RNA, molecular weight 5.46 X 10(4), and two approximately 17S and 17.5S RNA sequences with molecular weights of 6.04 X 10(5) and 6.61 X 10(5). The 17S and 17.5S RNAs of the large ribosomal subunits are formed in vivo from a 26S RNA precursor after assembly of the large ribosomal subunit. Large ribosomal subunits are transferred from the nucleus to the cytoplasm with the 26S RNA precursor intact. The hidden break to form the 17S and 17.5S RNAs is introduced in the cytoplasm. No intact 26S RNA could be detected in polysomes; this indicates that the conversion of the 26S RNA to the 17S and 17.5S RNAs may be required to produce large ribosomal subunits capable of participating in protein synthesis.

Isolation and characterization of polysomes from Trypanosoma brucei

The isolation of polysomes in bulk from bloodstream forms of Trypanosoma brucei is described. The polysomes are active in in vitro protein synthesis in the presence or absence of initiation inhibitors. Nascent variant surface antigen (VSA) has been detected on these polysomes using purified radio-iodinated antibody. EDTA-induced ribosomal sub-units and their large rRNA's are characterized. The 26S rRNA is nicked to produce 2 molecules which are both smaller than the 19S rRNA of the small sub-unit which is larger than that found in the majority of eukaryotic small sub-units.

In vitro ribosomal ribonucleoprotein transport upon nuclear expansion

The interdependence of nuclear rRNA release and nuclear size is investigated in macronuclei isolated from Tetrahymena. Nuclei are induced to contract and to expand, without any structural disintegration of the nuclear envelope, by final Ca2+/Mg2+ (3:2) concentrations of 5 and 1.5 mM, respectively. Upon expansion, the average volume of nuclei increases from 600 +/- 42 to 811 +/- 76 micron3. Concomitantly, nuclei begin to release RNA following saturation kinetics. This RNA release stops immediately upon nuclear contraction. Similar to the in vivo situation, only advanced rRNA processing products are released in the form of ribosomal precursor particles, as identified in detail by polyacrylamide gel electrophoresis and rate zonal and isopycnic density gradient centrifugation. Three particle ty9es are released having average buoyant densities of 1.495, 1.470, and 1.532 g/cm3, exhibiting average sedimentation coefficients of 62, 62, and 35 S, and containing the immediate precursor to the 25S rRNA, 26S rRNA, and 17S rRNA, respectively. Tje rRNP release if ATP independent and noncoincident with the release of endogenous nuclear Pi, though it is Be2+ sensitive. Our data are compatible with the views that nuclear expansion is the prerequisite rather than the cause for the rRNP release and that nuclear pore complex associated ATPases play only, if at all, a minor role in nucleocytoplasmic exchange of rRNP.

6.5 S RNA; preliminary characterisation of unusual small RNAs in Trypanosoma brucei

In this paper we report the preliminary characterisation of some unusual small rRNAs isolated from Trypanosoma brucei. These molecules correspond closely in size and properties to the 5 S and 5.8 S rRNAs of other eukaryotes and in addition there are two further small RNAs which we designate 6.5 S RNA. These have been characterised by sucrose gradient centrifugation and electrophoresis in denaturing gels. The two 6.5 S RNAs may be distinguished from each other on the basis of their size and the different conditions required for their dissociation from the ribosomes. They are present in the same abundance as 5.8 S RNA suggesting that they occur once per ribosome.