[Biochemical research on oogenesis. 7. Synthesis and maturation of 5S RNA in the small oocytes of Xenopus laevis]

Transcription termination by the eukaryotic RNA polymerase III

RNA polymerase (pol) III transcribes a multitude of tRNA and 5S rRNA genes as well as other small RNA genes distributed through the genome. By being sequence-specific, precise and efficient, transcription termination by pol III not only defines the 3' end of the nascent RNA which directs subsequent association with the stabilizing La protein, it also prevents transcription into downstream DNA and promotes efficient recycling. Each of the RNA polymerases appears to have evolved unique mechanisms to initiate the process of termination in response to different types of termination signals. However, in eukaryotes much less is known about the final stage of termination, destabilization of the elongation complex with release of the RNA and DNA from the polymerase active center. By comparison to pols I and II, pol III exhibits the most direct coupling of the initial and final stages of termination, both of which occur at a short oligo(dT) tract on the non-template strand (dA on the template) of the DNA. While pol III termination is autonomous involving the core subunits C2 and probably C1, it also involves subunits C11, C37 and C53, which act on the pol III catalytic center and exhibit homology to the pol II elongation factor TFIIS and TFIIFα/β respectively. Here we compile knowledge of pol III termination and associate mutations that affect this process with structural elements of the polymerase that illustrate the importance of C53/37 both at its docking site on the pol III lobe and in the active center. The models suggest that some of these features may apply to the other eukaryotic pols. This article is part of a Special Issue entitled: Transcription by Odd Pols.

Adenylation of small RNAs in human cells. Development of a cell-free system for accurate adenylation on the 3'-end of human signal recognition particle RNA

The 3'-end sequences of several human small RNAs were determined, and the results show that a fraction of human cytoplasmic 7SL, ribosomal 5S, and nuclear U2, U6, and 7SK small RNAs contain a post-transcriptionally added adenylic acid residue on their 3'-ends. Incubation of HeLa cell extract in vitro in the presence of [alpha-32P]ATP resulted in labeling of several small RNAs including ribosomal 5S and cytoplasmic 7SL as well as U2 and U6 small nuclear RNAs. Analysis of 7SL RNA labeled in this in vitro adenylation system showed that a single adenylic acid residue is added to the 3'-end. These results show that the adenylation observed in the in vitro system reflects the post-transcriptional adenylation occurring in vivo.

Ribosomal 5 S rRNA maturation in Saccharomyces cerevisiae

The maturation of the ribosomal 5 S RNA in Saccharomyces cerevisiae is examined based on the expression of mutant 5 S rRNA genes, in vivo, and a parallel analysis of RNA processing, in vitro. Both types of analysis indicate that 5 S rRNA processing is not dependent on the nucleotide sequence of either the external transcribed spacer or the mature 5 S rRNA. The results further indicate the RNA is processed by an exonuclease activity which is limited primarily or entirely by helix I, the secondary structure formed between the mature and interacting termini. The 5 S RNA binding protein (YL3) also appears not to influence directly the maturation process, but rather to play a role in protecting the rRNA from further degradation by "housekeeping" nucleases. Taken together, the results continue to support a "quality control" function which helps to ensure that during maturation only normal precursors are processed and assembled into active ribosomes.

A possible role for the 60-kD Ro autoantigen in a discard pathway for defective 5S rRNA precursors

The Ro autoantigen is a 60-kD protein that is usually found in small cytoplasmic RNA-protein complexes known as Ro RNPs. Although the Ro RNPs are abundant and conserved components of a variety of vertebrate and invertebrate cells, their function is unknown. We have discovered that the Ro protein is also found complexed with certain variant 5S rRNAs in Xenopus oocytes. These RNAs contain one or more point mutations compared with the major oocyte 5S rRNA sequence as well as additional nucleotides at the 3' end. We demonstrate that the Ro protein binds specifically mutant 5S rRNAs containing 3' terminal extensions. These mutant RNAs are processed inefficiently to mature 5S rRNA and most eventually are degraded. The observation that the Ro autoantigen specifically associates with defective 5S rRNA precursors suggests that this protein may function as part of a novel quality control or discard pathway for 5S rRNA production.

Transcription termination by RNA polymerase III: uncoupling of polymerase release from termination signal recognition

Xenopus RNA polymerase III specifically initiates transcription on poly(dC)-tailed DNA templates in the absence of other class III transcription factors normally required for transcription initiation. In experimental analyses of transcription termination using DNA fragments with a 5S rRNA gene positioned downstream of the tailed end, only 40% of the transcribing polymerase molecules terminate at the normally efficient Xenopus borealis somatic-type 5S rRNA terminators; the remaining 60% read through these signals and give rise to runoff transcripts. We find that the nascent RNA strand is inefficiently displaced from the DNA template during transcription elongation. Interestingly, only polymerases synthesizing a displaced RNA terminate at the 5S rRNA gene terminators; when the nascent RNA is not displaced from the template, read-through transcripts are synthesized. RNAs with 3' ends at the 5S rRNA gene terminators are judged to result from authentic termination events on the basis of multiple criteria, including kinetic properties, the precise 3' ends generated, release of transcripts from the template, and recycling of the polymerase. Even though only 40% of the polymerase molecules ultimately terminate at either of the tandem 5S rRNA gene terminators, virtually all polymerases pause there, demonstrating that termination signal recognition can be experimentally uncoupled from polymerase release. Thus, termination is dependent on RNA strand displacement during transcription elongation, whereas termination signal recognition is not. We interpret our results in terms of a two-step model for transcription termination in which polymerase release is dependent on the fate of the nascent RNA strand during transcription elongation.

Transcription termination by RNA polymerase III: uncoupling of polymerase release from termination signal recognition

Xenopus RNA polymerase III specifically initiates transcription on poly(dC)-tailed DNA templates in the absence of other class III transcription factors normally required for transcription initiation. In experimental analyses of transcription termination using DNA fragments with a 5S rRNA gene positioned downstream of the tailed end, only 40% of the transcribing polymerase molecules terminate at the normally efficient Xenopus borealis somatic-type 5S rRNA terminators; the remaining 60% read through these signals and give rise to runoff transcripts. We find that the nascent RNA strand is inefficiently displaced from the DNA template during transcription elongation. Interestingly, only polymerases synthesizing a displaced RNA terminate at the 5S rRNA gene terminators; when the nascent RNA is not displaced from the template, read-through transcripts are synthesized. RNAs with 3' ends at the 5S rRNA gene terminators are judged to result from authentic termination events on the basis of multiple criteria, including kinetic properties, the precise 3' ends generated, release of transcripts from the template, and recycling of the polymerase. Even though only 40% of the polymerase molecules ultimately terminate at either of the tandem 5S rRNA gene terminators, virtually all polymerases pause there, demonstrating that termination signal recognition can be experimentally uncoupled from polymerase release. Thus, termination is dependent on RNA strand displacement during transcription elongation, whereas termination signal recognition is not. We interpret our results in terms of a two-step model for transcription termination in which polymerase release is dependent on the fate of the nascent RNA strand during transcription elongation.

A 3' exonuclease activity degrades the pseudogene 5S RNA transcript and processes the major oocyte 5S RNA transcript in Xenopus oocytes

Transcription of the major oocyte 5S RNA gene (o) and pseudogene (psi) of Xenopus laevis yields different RNAs with three different homologous systems: oocyte microinjection, whole oocyte extract, and fractionated TFIIIA + TFIIIB + TFIIIC components. Those peculiar results are caused by a 3' RNA exonuclease activity, which is inhibited in the oocyte extract, that rapidly degrades the pseudogene 5S RNA but does not degrade as readily the chimeric RNA transcripts generated by HindIII-truncated 5S RNA pseudogenes. The same, or a similar, RNase activity processes the 130- and the 142-base-long transcripts of the major oocyte 5S RNA gene into mature 120-base-long 5S RNA. We performed site-specific mutagenesis on the somatic 5S RNA gene and changed specific nucleotides on the somatic 5S RNA. These studies indicated that the structure that confers stability to the 5S RNA in vivo and in vitro is the 9-bp helix formed in 5S RNA, but not in psi 5S RNA, by the complementary 5' and 3' ends of the molecule.

Identification of the binding site on 5S rRNA for the transcription factor IIIA: proposed structure of a common binding site on 5S rRNA and on the gene

Transcription factor IIIA interacts specifically with an internal control region of Xenopus 5S ribosomal RNA genes and is also a component, along with 5S rRNA, of a 7S ribonucleoprotein particle present in previtellogenic oocytes. We have determined the region of the 5S rRNA in the 7S ribonucleoprotein complex that is protected by the transcription factor from digestion with the ribonuclease alpha-sarcin. The binding site for factor IIIA extends from nucleotide 64 through nucleotide 116; the protected region includes two CCUGG helices separated by 11 nucleotides. The same helices occur in the factor IIIA binding site in the 5S rRNA gene and may constitute a common structural feature recognized by the protein in the gene and in the gene product.

Precursor molecules of both human 5S ribosomal RNA and transfer RNAs are bound by a cellular protein reactive with anti-La lupus antibodies

The small ribonucleoproteins recognized by anti-La autoantibodies contain a heterogeneous mixture of small RNAs from uninfected mammalian cells. The identity of many of these has now been established by the discovery of precursor forms of 5S rRNA and of certain tRNAs among La RNAs from HeLa cells. The small fraction of 5S rRNA molecules that exist as La ribonucleoproteins in vivo possess 1 or 2 additional U residues at their 3' ends. Such 5S molecules bound to the La protein have also been identified with in vitro nuclear transcription systems. Pulse-chase experiments performed both in vivo and in vitro support the idea that most newly synthesized 5S rRNA molecules are transiently associated with the La protein. Cell extracts contain a processing activity that converts longer in vitro-synthesized 5S RNA transcripts into molecules of mature size. The presence of in vivo tRNA precursors in the heterogeneous mixture of La RNAs is demonstrated by the identification of precursor forms of five different specific tRNAs (Meti, Asp, Gly, Glu, Asn). After in vitro transcription of a tRNA gene (tRNAiMet), only products the size of precursor molecules are precipitable by anti-La antibodies. The realization that virtually every known RNA polymerase III product associates at least initially with the La antigen suggests that this protein plays an essential role in the synthesis or maturation of all class III transcripts.

Transcription of Xenopus 5S ribosomal RNA genes

The accurate transcription of 5S RNA genes when injected into the nucleus of Xenopus oocytes or when added to an in vitro transcription system has allowed identification of the DNA sequences and one of the protein factors required for 5S RNA synthesis. Moreover, 5S RNA genes as part of intact chromosomes maintain a transcriptionally regulated state when injected into Xenopus oocyte nuclei. A detailed picture of the developmental regulation of 5S RNA gene expression is now emerging.

In vitro transcription of cloned 5S RNA genes of the newt Notophthalmus

Recombinant plasmids that carried genes coding for 5S ribosomal RNA of the newt, Notophthalmus viridescens, were transcribed in vitro with extracts of Xenopus laevis oocyte nuclei. Plasmids containing multiple repeats of the 5S gene and spacer directed accurate transcription of 5S RNA (120 bases). Individual repeat units were recloned by inserting Sau 3A restriction fragments into the Bam HI site of plasmid pBR322. Because each repeat was cut by the enzyme within the coding region, the inserts had incomplete coding regions at their ends and spacer sequences in the middle. The DNA of these subclones directed synthesis of a 5S-size RNA that contained both plasmid and 5S RNA sequences. Transcription initiated in the vector, proceeded through the gene segment coding for nucleotides 41-120, and terminated at the end of the gene. The initiation of in vitro transcription required neither the original 5' flanking sequences of the spacer nor the first third of the gene. We conclude that intragenic DNA sequences control the initiation of transcription. Other subclones that include pseudogenes gave rise to some transcripts 156 nucleotides long. These long transcripts represented continuation of transcription through the 36-base-pair pseudogene that is located immediately downstream from the 5S gene. However, most transcripts of these subclones terminated at the end of the normal gene before the beginning of the pseudogene. It is probable that a run of four or more Ts serves as part of the termination signal.

Identification of a novel class of tandemly repeated genes transcribed on lampbrush chromosomes of Pleurodeles waltlii

Electron microscope preparations of lampbrush chromosomes from oocytes of Pleurodeles waltlii have revealed a new class of tandemly repeated genes. These genes are highly active, as judged by the close spacing of nascent transcripts. They occur in clusters of greater than 100 copies and are transcribed in units containing roughly 940 base pairs of DNA that are separated by nontranscribed spacers of an estimated DNA content of 2,410 base pairs. The size and the pattern of arrangement of these transcription units can not be correlated with any of the repetitious genes so far described.

In vitro synthesis of a 5S RNA precursor by isolated nuclei of rat liver and HeLa cells

Isolated rat liver nuclei were incubated under appropriate conditions in the presence of 0.5 micrograms/ml alpha-amanitin and an RNAase inhibitor prepared from cytosol fraction, together with alpha-32P-UTP or alpha-32P-CTP and three other nucleoside triphosphates. RNA extracted by an SDS-hot phenol procedure was fractionated with sucrose density gradient centrifugation followed by acrylamide gel electrophoresis. Fingerprint analysis of the in vitro synthesized "5S" RNA, which was slightly larger than mature 5S RNA on gel electrophoresis, showed that it contained all the sequences of mature 5S RNA except for the oligonucleotide at the 3' end. Instead, it contained two additional spots which were not present in mature 5S RNA. Analysis of the extra spots revealed that they were derived from the 3' end of the in vitro synthesized "5S RNA, which were sequenced tentatively as -CUUGAUGCUUoh (extra sequence underlined). The 5' end of the product was (p)pGU--. Isolated HeLa cell nuclei synthesized similar sized "5S" RNA under the same conditions. We conclude from these results that in isolated nuclei of these mammalian cells RNA polymerase III starts transcription of 5S RNA gene at the same site as the 5' end of mature 5S RNA, proceeds toward the 3' direction and stops at a site probably 8 nucleotides downstream from the 3' end of mature 5S RNA. Experiments with a short pulse and with various "chases" have demonstrated the presence of a short-lived precursor 5S RNA which is similar in size and sequence to in vitro "5S" RNA, suggesting that 5S RNA is synthesized in vivo as a longer precursor molecular as demonstrated in this in vitro system, and is rapidly processed into mature 5S RNA.

Nucleotide sequence of Xenopus borealis oocyte 5S DNA: comparison of sequences that flank several related eucaryotic genes

Genomic Xenopus borealis oocyte-specific 5S DNA (Xbo) contains clusters of 5S rRNA genes. The number of genes varies among clusters, and the distance between genes within a cluster is about 80 nucleotides. The spacer DNA between gene clusters is AT-rich and heterogeneous in length due in part to variable numbers of a tandemly repeated 21 nucleotide sequence. A cloned fragment of Xbo 5S DNA (Xbo1) containing three 5S rRNA genes has been sequenced. The sequences of Xbo1 genes 1 and 2 are very similar to the dominant 5S RNA sequence, whereas 15 of the 120 residues in the third gene are different. The sequence of gene 3 is as different from the dominant gene sequence as the X. laevis pseudogene is from the 5S RNA gene. Sequence analysis of genomic DNA shows that gene 3 is an abundant component of the multigene family. All three genes are transcribed when added to an extract of X. laevis oocyte nuclei, and a fragment of Xbo1 lacking the AT-rich spacer DNA and the 5' end of the first gene supports transcription of genes 2 and 3 in this in vitro system. Thus the 80 nucleotides preceding each 5S gene are sufficient for promoter function. Nucleic acid sequences preceding several eucaryotic genes that are transcribed by RNA polymerase III were analyzed and the following common features were found: a purine-rich region; at least one direct repeat; the absence of dyad symmetry; transcription beginning with a purine; a pyrimidine residue immediately preceding the first nucleotide of the gene; and the oligonucleotides AAAAG, AGAAG and GAC, located approximately 15, 25 and 35 nucleotides, respectively, before the start of transcription. The 10 base pair (bp) spacing between the homologous oligonucleotides is that expected for a recognition signal on one face of a DNA double helix. The extensive sequence differences between most of the spacers that precedes these genes make the three conserved oligonucleotides more striking. Parts of the 5' flanking regions of the three Xbo1 gene (-12 to -40), which include the conserved oligonucleotides, are identical. In contrast, 7 of the first 11 nucleotides that precede the third 5S RNA gene in Xbo1 differ from those that precede the first gene. The sequences following the X. borealis oocyte and somatic 5S genes are identical in 12 of the first 14 residues and contain two or more T clusters, as does the corresponding region of X. laevis oocyte 5S DNA. The 3' sequences of the Xenopus 5S rRNA genes and several other eucaryotic genes contain features in common with procaryotic transcription termination sites. The 3' end of the gene is GC-rich and contains a dyad symmetry. Termination occurs in an AT-rich region containing one or more T clusters on the noncoding strand.

The nucleotide sequence of oocyte 5S DNA in Xenopus laevis. II. The GC-rich region

The primary sequence of the GC-rich half of the repeating unit in X. laevis 5S DNA has been determined in both a single plasmid-cloned repeating unit and in the total population of repeatig units. The GC-rich half of the repeating unit contains a single long duplication of 174 nucleotides. The duplicated segment commences 73 nucleotides preceding the 5' end of the gene and terminates at nucleotide 101 of the gene. The duplicated portion of the gene, termed the pseudogene, differs by 10 nucleotides from the corresponding portion of the gene, and the remaining duplicated sequence of 73 nucleotides differs by 13 nucleotides. The plasmid-cloned repeating unit differs from the dominant sequence in the total population repeating units by 6 nucleotides in the GC-rich region. Evidence is provided that most of the CpG dinucleotides in 5S DNA are at least partially methylated.

A pseudogene structure in 5S DNA of Xenopus laevis

The 5S DNA of Xenopus laevis, coding for oocyte-type 5S RNA, consists of many copies of a tandemly repeated unit of about 700 base pairs. Each unit contains a "pseudogene" in addition to the gene. The pseudogene has been partly sequenced and appears to be an almost perfect repeat of 101 residues of the gene. The order of components in the repeat unit is (5') long spacer--gene--linker--pseudogene (3') in the "+" strand (or H strand) of the DNA. The possible function of the pseudogene is discussed.

Identification of the lampbrush chromosome loops which transcribe 5S ribosomal RNA in Notophthalmus (Triturus) viridescens

The loops which transcribe 5S ribosomal RNA in lampbrush chromosomes of the newt, Notophthalmus (Triturus) viridescens, were identified by hybridizing purified 5S DNA to nascent 5S RNA in situ. The genes which code for 5S RNA were found near the centromeres of chromosomes 1, 2, 6, and 7 by hybridizing iodinated 5S RNA to denatured lampbrush and mitotic chromosomes in situ. These genes and their intervening spacer DNA were isolated from Xenopus laevis using sequential silver-cesium sulfate equilibrium centrifugations. This purified 5S DNA was iodinated and hybridized to non-denatured lampbrush chromosomes in situ, where it bound to nascent 5S RNA on loops at the base of the centromeres of chromosomes 1, 2, 6, and 7. The number of 5S genes present in the haploid chromosome complement of N. viridescens was determined. - The 5S loops were chosen for study, since (1) the synthesis of 5S RNA has been demonstrated during the lampbrush stage, (2) both 5S RNA and 5S DNA could be isolated in pure form, and (3) the localization of the repetitive 5S genes could be verified by conventional in situ hybridization procedures. These methods may be applicable to the identification of other loops, leading to a better understanding of lampbrush chromosome function.

Biochemical research on oogenesis. Comparison between transfer RNAs from somatic cells and from oocytes in Xenopus laevis

The properties of tRNA from oocytes of Xenopus laevis were compared with those of tRNA from somatic cells of the same species. Both types of tRNAs were found to have the same average length and to contain an equal variety of modified nucleotides. However, tRNA from small oocytes differed from somatic tRNA by its chromatographic behavior on methylated-albumin kieselguhr columns. The elution profiles from reversed-phase chromatography 5 columns of several aminoacyl tRNAs were compared after charging somatic and oocyte tRNSs with 3H or 14C-labelled amino acids. Striking differences in peak position were observed when tRNA from small oocytes was mixed and co-chromatographed with somatic tRNA. The differences were less important when tRNAs from large oocytes and from somatic cells were compared. Mixtures of egg and somatic tRNAs gave completely or almost completely coincident elution profiles. Only one isoacceptor, tNRA1Met (initiator tRNA) had the same position in all reversed-phase chromatography 5 chromatograms. The results are discussed in terms of possible post-transcriptional modifications of tRNA in the course of oogenesis. An alternative explanation resorting to changes in the tRNA population of the growing oocyte is also envisaged.

Effect of heat shock on the synthesis of low molecular weight RNAs in drosophilia: accumulation of a novel form of 5S RNA

The synthesis and stability of low molecular weight RNAs following heat shock in Drosophilia melanogaster cell cultures have been examined. When cultures are raised from 25 degrees C to 37 degrees C, the synthesis of tRNA and at least two other low molecular weight RNAs continues at the 25 degree C rate. 5.8S ribosomal RNA and most of the low molecular weight nuclear RNAs are not synthesized. The synthesis of 5S ribosomal RNA is greatly reduced. A large amount of an RNA of about 135 nucleotides in length accumulates at 37 degrees C. Nucleotide sequence analysis reveals that this RNA is a novel form of 5S RNA with approximately 15 additional nucleotides at its 3' end.