A supraspliceosome model for large nuclear ribonucleoprotein particles based on mass determinations by scanning transmission electron microscopy.

Pre-mRNA splicing is an important regulatory step in the expression of most eukaryotic genes. In vitro studies have shown splicing to occur within 50-60 S multi-component ribonucleoprotein (RNP) complexes termed spliceosomes. Studies of mammalian cell nuclei have revealed larger complexes that sediment at 200 S in sucrose gradients, termed large nuclear RNP (lnRNP) particles. These particles contain all factors required for pre-mRNA splicing, including the spliceosomal U snRNPs and protein splicing factors. Electron microscopy has shown them to consist of four apparently similar substructures. In this study, mass measurements by scanning transmission electron microscopy of freeze-dried mammalian lnRNP preparations, both confirm the similarity between the lnRNP particles and reveal the mass uniformity of their subunits. Thus, the tetrameric lnRNP particle has a mass of 21.1(+/-1.6) MDa, while each repeating subunit has a mass of 4.8(+/-0.5) MDa, which is close to the estimated mass of the fully assembled 60 S spliceosome. The 1.9 MDa discrepancy between the lnRNP particle's mass and the cumulative masses of its four subunits may be attributed to an additional domain frequently observed in the micrographs. Notably, strands and loops of RNA were often seen emanating from lnRNP particles positively stained with uranyl formate. Our results support the idea that the nuclear splicing machine is a supraspliceosome complex. For clarity, we define spliceosomes devoid of pre-mRNA as spliceosome cores, and propose that the supraspliceosome is constructed from one pre-mRNA, four spliceosome cores, each composed mainly of U snRNPs, and additional proteins. In this way a frame is provided to juxtapose exons about to be spliced.

Three-dimensional image reconstruction of large nuclear RNP (lnRNP) particles by automated electron tomography.

Nuclear RNA transcripts of split genes and their splicing products, as well as the general population of nuclear polyadenylated RNA are packaged in multi-component large nuclear ribonucleoprotein (lnRNP) particles. These lnRNP particles, which sediment at the 200 S region in sucrose gradients, contain all U small nuclear RNPs required for precursor messenger RNA (pre-mRNA) splicing and several protein splicing factors, including U2AF and the SR proteins. Electron microscopy of lnRNP particles revealed a large compact structure of 50 nm in diameter. In this study we employed automated computed tomography from electron micrographs for the three-dimensional (3D) image reconstruction of individual lnRNP particles isolated from mammalian cells nuclei and negatively stained. For each particle, a tilt series of 71 images was collected by direct digital recording of the images on a CCD camera attached to a computer controlled TEM facility. The 3D image was reconstructed according to the back projection principle. For rendering, real time display and comparison of the reconstructed particles, interactive computer graphics was employed. The reconstructed 3D images show a compact structure composed of four major subunits connected to each other. Comparison of the reconstructed lnRNP particles revealed morphological similarity of the individual particles, as well as similarity among the sub-structures. Based on these observations we propose a model for the packaging of nuclear pre-mRNAs in lnRNP particles where each substructure represents a functional unit. This model is compatible with the requirements for alternative splicing in multi-intronic pre-mRNAs, and with the fact that the splicing of multi-intronic pre-mRNAs does not occur in a sequential manner.

Automated electron tomography of large nuclear RNP (InRNP) particles--the naturally assembled complexes of precursor messenger RNA and splicing factors.

Splicing of nuclear pre-mRNA is an important step in the regulation of gene expression as only correctly spliced mRNAs will be exported to the cytoplasm to function in protein synthesis. Nuclear RNA transcripts of split genes and their splicing products, as well as the general population of nuclear polyadenylated RNA, are packaged in multicomponent large nuclear ribonucleoprotein (lnRNP) particles. These lnRNP particles, which sediment at the 200S region in sucrose gradients, contain all U snRNPs required for pre-mRNA splicing and several protein splicing factors, including U2AF and the SR proteins and can thus be viewed as naturally assembled complexes of pre-mRNA and splicing factors. We have previously reconstructed the three-dimensional image of negatively stained individual lnRNP particles by automated electron tomography. The reconstruction revealed a compact structure, 50 nm in diameter, composed of four major subunits. Here we further analyzed the reconstructed models and the apparent connectivity between the subunits using a new rendering technique. The uniformity of the lnRNP particles was substantiated by measurement of the volume engulfed by their surface. This study further supports the model proposed for the packaging of nuclear pre-mRNAs in lnRNP particles, where each substructure represents a functional unit. This model is compatible with the requirements for alternative splicing in multiintronic pre-mRNAs, and with the fact that the splicing of multiintronic pre-mRNAs does not occur in a sequential manner.

Magnesium cations are required for the association of U small nuclear ribonucleoproteins and SR proteins with pre-mRNA in 200 S large nuclear ribonucleoprotein particles.

In previous studies we have shown that specific nuclear pre-mRNAs and their splicing products, as well as the general population of nuclear poly(A)+ RNA, are found packaged in 200 S large nuclear ribonucleoprotein (lnRNP) particles that represent the splicing machinery in vivo. The lnRNP particles contain all U small nuclear ribonucleoproteins (snRNPs) required for splicing, as well as several proteins including non-snRNP splicing factors. Here we show that upon addition of EDTA to sucrose gradient-fractionated 200 S particles, part of their components (e.g. part of the U snRNPs) are no longer associated with pre-mRNAs, which are now packaged in 70 S particles. This 200 S to 70 S transition makes the pre-mRNA more susceptible to digestion by RNase. The effect of EDTA is reversible, as back addition of Mg2+ results in the reconstitution into 200 S lnRNP particles of: (1) all five snRNPs required for splicing; (2) the SR proteins; and (3) CAD mRNA, as a representative of nuclear RNA polymerase II transcripts. Remarkably, electron microscopy of the reconstituted particles shows a compact structure, 50 nm in diameter, that is indistinguishable from the original undissociated particles. We conclude that Mg2+ is required for the integrity of the 200 S lnRNP particles.