Two different snoRNAs are encoded in introns of amphibian and human L1 ribosomal protein genes.

We previously reported that the third intron of the X.laevis L1 ribosomal protein gene encodes for a snoRNA called U16. Here we show that four different introns of the same gene contain another previously uncharacterized snoRNA (U18) which is associated with fibrillarin in the nucleolus and which originates by processing of the pre-mRNA. The pathway of U18 RNA release from the pre-mRNA is the same as the one described for U16: primary endonucleolytic cleavages upstream and downstream of the U18 coding region produce a pre-U18 RNA which is subsequently trimmed to the mature form. Both the gene organization and processing of U18 are conserved in the corresponding genes of X.tropicalis and H.sapiens. The L1 gene thus has a composite structure, highly conserved in evolution, in which sequences coding for a ribosomal protein are intermingled with sequences coding for two different snoRNAs. The nucleolar localization of these different components suggests some common function on ribosome biosynthesis.     

A synthetic histone pre-mRNA-U7 small nuclear RNA chimera undergoing cis cleavage in the cytoplasm of Xenopus oocytes.

The 3' processing of histone pre-mRNAs is a nuclear event in which the U7 small nuclear ribonucleoprotein (snRNP) participates as an essential trans-acting factor. We have constructed a chimeric histone-U7 RNA that when injected into the cytoplasm of Xenopus laevis oocytes assembles into a snRNP-like particle and becomes cleaved at the correct site(s). RNP assembly is a prerequisite for cleavage, but, since neither the RNA nor the RNP appreciably enter the nucleus, cleavage occurs mostly, if not exclusively, in the cytoplasm. Consistent with this, cleavage also occurs in enucleated oocytes or in oocytes which have been depleted of U7 snRNPs. Thus all necessary components for cleavage must be present in the oocyte cytoplasm. The novel cleavage occurs in cis, involving only a single molecule of chimeric RNA with its associated proteins. This reaction is equally dependent upon base pairing interactions between histone spacer sequences and the 5'-end of the U7 moiety as the natural in trans reaction. These results imply that U7 is the only snRNP required for histone RNA processing. Moreover, the chimeric RNA is expected to be useful for further studies of the cleavage and assembly mechanisms of U7 snRNP.     

Ribosomal protein L2 in Saccharomyces cerevisiae is homologous to ribosomal protein L1 in Xenopus laevis. Isolation and characterization of the genes

By cross-hybridization with a cDNA probe for the Xenopus laevis ribosomal protein L1 we have been able to isolate the homologous genes from a Saccharomyces cerevisiae genomic library. We have shown that these genes code for a ribosomal protein which was previously named L2. In yeast, like in X. laevis, these genes are present in two copies per haploid genome and, unlike the vertebrate counterpart, they do not contain introns. Amino acid comparison of the X. laevis L1 and S. cerevisiae L2 proteins has shown the presence of a highly conserved protein domain embedded in very divergent sequences. Although these sequences are very poorly homologous, they confer an overall secondary structure and folding highly conserved in the two species.     

A novel small nucleolar RNA (U16) is encoded inside a ribosomal protein intron and originates by processing of the pre-mRNA.

We report that the third intron of the L1 ribosomal protein gene of Xenopus laevis encodes a previously uncharacterized small nucleolar RNA that we called U16. This snRNA is not independently transcribed; instead it originates by processing of the pre-mRNA in which it is contained. Its sequence, localization and biosynthesis are phylogenetically conserved: in the corresponding intron of the human L1 ribosomal protein gene a highly homologous region is found which can be released from the pre-mRNA by a mechanism similar to that described for the amphibian U16 RNA. The presence of a snoRNA inside an intron of the L1 ribosomal protein gene and the phylogenetic conservation of this gene arrangement suggest an important regulatory/functional link between these two components.     

Identification of the RNA binding segment of human U1 A protein and definition of its binding site on U1 snRNA.

The interaction between the U1 snRNP-specific U1 A protein and U1 snRNA has been analysed. The binding site for the protein on the RNA is shown to be in hairpin II, which extends from positions 48 to 91 in the RNA. Within this hairpin the evolutionarily conserved loop sequence is crucial for interaction with U1 A protein. U1 A protein can also bind the loop sequence when it is part of an artificial RNA which cannot form a stable hairpin structure. The region of the protein required to bind to U1 snRNA consists of a conserved 80 amino acid motif, previously identified in many ribonucleoprotein (RNP) proteins, together with (maximally) 11 N-terminal and 10 C-terminal flanking amino acids. Point mutations introduced into two of the most highly conserved regions of this motif abolish RNA binding. U1 snRNA mutants from which the U1 A binding site has been deleted are shown to be capable of assembly into RNP particles which are immunoprecipitable by patient antisera which recognize U1 A protein. The role of RNA-protein and protein-protein interactions in U snRNP assembly are discussed.     

RNA-protein interactions of stored 5S RNA with TFIIIA and ribosomal protein L5 during Xenopus oogenesis

We studied the pathway of 5S RNA during oogenesis in Xenopus laevis from its storage in the cytoplasm to accumulation in the nucleus, the sequence requirements for the 5S RNA to follow that pathway, and the 5S RNA-protein interactions that occur during the mobilization of stored 5S RNA for assembly into ribosomes. In situ hybridization to sections of oocytes indicates that 5S RNA first becomes associated with the amplified nucleoli during vitellogenesis when the nucleoli are activity synthesizing ribosomal RNA and assembling ribosomes. When labeled 5S RNA is microinjected into the cytoplasm of stage V oocytes, it migrates into the nucleus, whether microinjected naked or complexed with the protein TFIIIA as a 7S RNP storage particle. During vitellogenesis, a nonribosome bound pool of 5S RNA complexed with ribosomal protein L5 (5S RNPs) is formed, which is present throughout the remainder of oogenesis. Immunoprecipitation assays on homogenates of microinjected oocytes showed that labeled 5S RNA can become complexed either with L5 or with TFIIIA. Nucleotides 11 through 108 of the 5S RNA molecule provide the necessary sequence and conformational information required for the formation of immunologically detectable complexes with TFIIIA or L5 and for nuclear accumulation. Furthermore, labeled 5S RNA from microinjected 7S RNPs can subsequently become associated with L5. Such labeled 5S RNA is found in both 5S RNPs and 7S RNPs in the cytoplasm, but only in 5S RNPs in the nucleus of microinjected oocytes. These data suggest that during oogenesis a major pathway for incorporation of 5S RNA into nascent ribosomes involves the migration of 5S RNA from the nucleus to the cytoplasm for storage in an RNP complex with TFIIIA, exchange of that protein association for binding with ribosomal protein L5, and a return to the nucleus for incorporation into ribosomes as they are being assembled in the amplified nucleoli.