Jutta Rinke

Localization of a base-paired interaction between small nuclear RNAs U4 and U6 in intact U4/U6 ribonucleoprotein particles by psoralen cross-linking.

The small nuclear RNAs U4 and U6 display extensive sequence complementarity and co-exist in a single ribonucleoprotein particle. We have investigated intermolecular base-pairing between both RNAs by psoralen cross-linking, with emphasis on the native U4/U6 ribonucleoprotein complex. A mixture of small nuclear ribonucleoproteins U1 to U6 from HeLa cells, purified under non-denaturing conditions by immune affinity chromatography with antibodies specific for the trimethylguanosine cap of the small nuclear RNAs was treated with aminomethyltrioxsalen. A psoralen cross-linked U4/U6 RNA complex could be detected in denaturing polyacrylamide gels. Following digestion of the cross-linked U4/U6 RNA complex with ribonuclease T1, two-dimensional diagonal electrophoresis in denaturing polyacrylamide gels was used to isolate cross-linked fragments. These fragments were analysed by chemical sequencing methods and their positions identified within RNAs U4 and U6. Two overlapping fragments of U4 RNA, spanning positions 52 to 65, were cross-linked to one fragment of U6 RNA (positions 51 to 59). These fragments show complementarity over a contiguous stretch of eight nucleotides. From these results, we conclude that in the native U4/U6 ribonucleoprotein particle, both RNAs are base-paired via these complementary regions. The small nuclear RNAs U4 and U6 became cross-linked in the deproteinized U4/U6 RNA complex also, provided that small nuclear ribonucleoproteins were phenolized at 0 degree C. When the phenolization was performed at 65 degrees C, no cross-linking could be detected upon reincubation of the dissociated RNAs at lower temperature. These results indicate that proteins are not required to stabilize the mutual interactions between both RNAs, once they exist. They further suggest, however, that proteins may well be needed for exposing the complementary RNA regions for proper intermolecular base-pairing in the course of the assembly of the U4/U6 RNP complex from isolated RNAs. Our results are discussed also in terms of the different secondary structures that the small nuclear RNAs U4 and U6 may adopt in the U4/U6 ribonucleoprotein particle as opposed to the isolated RNAs.

Localization and structure of snRNPs during mitosis. Immunofluorescent and biochemical studies.

The distribution of U snRNAs during mitosis was studied by indirect immunofluorescence microscopy with snRNA cap-specific anti-m3G antibodies. Whereas the snRNAs are strictly nuclear at late prophase, they become distributed in the cell plasm at metaphase and anaphase. They re-enter the newly formed nuclei of the two daughter cells at early telophase, producing speckled nuclear fluorescent patterns typical of interphase cells. While the snRNAs become concentrated at the rim of the condensing chromosomes and at interchromosomal regions at late prophase, essentially no association of the snRNAs was observed with the condensed chromosomes during metaphase and anaphase. Independent immunofluorescent studies with anti-(U1)RNP autoantibodies, which react specifically with proteins unique to the U1 snRNP species, showed the same distribution of snRNP antigens during mitosis as was observed with the snRNA-specific anti-m3G antibody. Immunoprecipitation studies with anti-(U1)RNP and anti-Sm autoantibodies, as well as protein analysis of snRNPs isolated from extracts of mitotic cells, demonstrate that the snRNAs remain associated in a specific manner with the same set of proteins during interphase and mitosis. The concept that the overall structure of the snRNPs is maintained during mitosis also applies to the coexistence of the snRNAs U4 and U6 in a single ribonucleoprotein complex. Particle sedimentation studies in sucrose gradients reveal that most of the snRNPs present in sonicates of mitotic cells do not sediment as free RNP particles, but remain associated with high molecular weight (HMW) structures other than chromatin, most probably with hnRNA/RNP.

Random exchange of ribosomal proteins in EDTA sub-particles.

The use of EDTA to ‘unfold’ ribosomal sub-particles has been widespread over the last few years (see e.g. [I] for review). The EDTA particles retain most if not all of the ribosomal proteins [2], but it is not yet known whether the proteins in the unfolded particle retain their specific locations on the ribosomal RNA or whether their distribution becomes random. This is obviously an important consideration, when EDTA particles are used for studies on the organization of the ribosomal components. In particular, several authors have reported the isolation of specific ribo-nucleoprotein fragments from EDTA-treated [3-51 or de-salted [6] particles, which would suggest that the proteins remain specifically located on the RNA. However, in our own studies on specific fragments from E. coli ribosomes, we have been unable to obtain fragments from either the 30s or SOS sub-particles in the presence of EDTA which satisfy our rigorous criteria for specificity [7,8]. This has led us to suspect that in EDTA the proteins have lost their specific sites on the RNA, and in this paper we demonstrate that this is indeed the case, by examining the ability of the proteins to exchange between different ribosomal RNA’s or sub-particles.

The use of azidoarylimidoesters in RNA-protein cross-linking studies with Escherichia coli ribosomes

Abstract A series of related hetero-bifunctional RNA-protein cross-linking reagents has been prepared, carrying an imidoester or N -hydroxysuccinimide ester function at one end of the molecule, and a phenylazido function at the other. These compounds have been applied to RNA-protein cross-linking studies with ribosomal subunits, and one of them, p -azido-phenylacetic imidoester, has proved to be a particularly useful reagent for this purpose. The reagent first reacts specifically with protein amino groups, and subsequent photolysis of the azide group leads to cross-linking to the RNA in yields of up to 8% of the total protein. The whole reaction takes place under very mild conditions in aqueous solution. The individual proteins concerned in the cross-links have been identified by two-dimensional gel electrophoresis, and the existence of a covalent cross-link was confirmed by the isolation by two different methods of protein-oligonucleotide complexes carrying a 32 P label. Although most of the ribosomal proteins could be cross-linked to their corresponding ribosomal RNA within the individual subunits, RNA-protein cross-links at the ribosomal subunit interface were only detectable in vanishingly small amounts. The advantages of this type of genuine hetero-bifunctional reagent in RNA-protein cross-linking studies are discussed.

30S ribosomal proteins cross-linked to 16S RNA by periodate oxidation followed by borohydride reduction.

Gel electrophoretic techniques have been used to reexamine the RNA-protein cross-linking reaction induced by periodate oxidation and borohydride reduction of 30S ribosomal subunits. The results show that a number of 30S ribosomal proteins become attached to intact 16S RNA by this method, in addition to those already published. It follows that this cross-linking technique as it stands is of little value as a topographical probe of the environment of the 3′-terminus of the 16S RNA.