The yeast U4͞U6⅐U5 pre-mRNA splicing small nuclear ribonucleoprotein (snRNP) is a 25S small nuclear ribonucleoprotein particle similar in size, composition, and morphology to its counterpart in human cells. The yeast U4͞ U6⅐U5 snRNP complex has been purified to near homogeneity by affinity chromatography and preparative glycerol gradient sedimentation. We show that there are at least 24 proteins stably associated with this particle and performed mass spectrometry microsequencing to determine their identities. In addition to the seven canonical core Sm proteins, there are a set of U6 snRNP specific Sm proteins, eight previously described U4͞U6⅐U5 snRNP proteins, and four novel proteins. Two of the novel proteins have likely RNA binding properties, one has been implicated in the cell cycle, and one has no identifiable sequence homologues or functional motifs. The purification of the low abundance U4͞U6⅐U5 snRNP from yeast and the powerful sequencing methodologies using small amounts of protein make possible the rapid identification of novel and previously unidentified components of large, low-abundance macromolecular machines from any genetically manipulable organism.Eukaryotic pre-mRNA must undergo extensive processing in the nucleus before it is converted into the mature mRNA species competent for translation into protein. One important processing step is the excision of intervening sequences, termed introns, which are present within the coding sequences. Removal of introns is effected by the pre-mRNA splicing machinery, which is composed of five phylogenetically conserved small nuclear RNAs (snRNAs) assembled into small ribonucleoprotein particles (snRNPs) and several non-snRNP associated proteins (1). Once assembled onto pre-mRNA, the massive RNP termed the spliceosome removes the intronic RNA sequences by two ordered transesterification reactions ligating the two exons together, forming the mature message. The biochemistry of the mammalian spliceosomal snRNPs has been extensively studied, and many of the protein components have been purified and their genes cloned (2-4). The budding yeast Saccharomyces cerevisiae has been very useful in the study of pre-mRNA splicing, as it is amenable to genetic manipulations. The low abundance of premRNA splicing snRNPs, however, has made their isolation technically challenging. Several yeast proteins involved in splicing have been identified by conditional growth mutations that produce a pre-mRNA splicing defect (5-7) from synthetic lethal analysis (8, 9), identification of second-site suppressors (10-13), two-hybrid analysis (14), and, most recently, from the direct biochemical purification of the yeast U1 snRNP (15,16).In yeast, there are an estimated 100-200 copies of each spliceosomal snRNA (17) as compared with 100,000-1,000,000 snRNA copies in mammalian cells (18). This discrepancy in abundance has made the purification of yeast snRNPs much more difficult, especially in the case of the yeast U4͞U6⅐U5 tri-snRNP, which exists in equilibrium with the individual ...
