The human La (SS-B) autoantigen is an abundantly expressed putative RNA chaperone, functioning in various intracellular processes involving RNA. To further explore the molecular mechanisms by which La functions in these processes, we performed large-scale immunoprecipitations of La from HeLa S100 extracts using the anti-La monoclonal antibody SW5. La-associated proteins were subsequently identified by sequence analysis. This approach allowed the identification of DDX15 as a protein interacting with La. DDX15, the human ortholog of yeast Prp43, is a member of the superfamily of DEAH-box RNA helicases that appeared to interact with La both in vivo and in vitro. The region needed for the interaction with La partly overlaps the DEAH-box domain of DDX15. Immunofluorescence data indicated that endogenous DDX15 accumulates in U snRNP containing nuclear speckles in HEp-2 cells. Surprisingly DDX15 also accumulates in the nucleoli of HEp-2 cells. Moreover, DDX15 and La seem to colocalize in the nucleoli. Regions of DDX15 involved in nuclear, nuclear speckle, and nucleolar localization are located within the N- and C-terminal regions flanking the DEAH-box. RNA coprecipitation experiments indicated that DDX15 is associated with spliceosomal U small nuclear RNAs in HeLa cell extracts. The possible functional implications of the interaction between La and DDX15 are discussed.

Protein-dependent group II intron splicing provides a forum for exploring the roles of proteins in facilitating RNA-catalyzed reactions. The maize nuclear gene crs1 is required for the splicing of the group II intron in the chloroplast atpF gene. Here we report the molecular cloning of the crs1 gene and an initial biochemical characterization of its gene product. Several observations support the notion that CRS1 is a bona fide group II intron splicing factor. First, CRS1 is found in a ribonucleoprotein complex in the chloroplast, and cofractionation data provide evidence that this complex includes atpF intron RNA. Second, CRS1 is highly basic and includes a repeated domain with features suggestive of a novel RNA-binding domain. This domain is related to a conserved free-standing open reading frame of unknown function found in both the eubacteria and archaea. crs1 is the founding member of a gene family in plants that was derived by duplication and divergence of this primitive gene. In addition to its previously established role in atpF intron splicing, new genetic data implicate crs1 in chloroplast translation. The chloroplast splicing and translation functions of crs1 may be mediated by the distinct protein products of two crs1 mRNA forms that result from alternative splicing of the crs1 pre-mRNA.

Previous work from this laboratory (Nurse et al., RNA, 1995, 1:102–112) established that TruB, a pseudouridine (Ψ) synthase from Escherichia coli, was able to make Ψ55 in tRNA transcripts but not in transcripts of full-length or fragmented 16S or 23S ribosomal RNAs. By deletion of the truB gene, we now show that TruB is the only protein in E. coli able to make Ψ55 in vivo. Lack of TruB and Ψ55 did not affect the exponential growth rate but did confer a strong selective disadvantage on the mutant when it was competed against wild-type. The negative selection did not appear to be acting at either the exponential or stationary phase. Transformation with a plasmid vector conferring carbenicillin resistance and growth in carbenicillin markedly increased the selective disadvantage, as did growth at 42 °C, and both together were approximately additive such that three cycles of competitive growth sufficed to reduce the mutant strain to ∼0.2% of its original value. The most striking finding was that all growth effects could be reversed by transformation with a plasmid carrying a truB gene coding for a D48C mutation in TruB. Direct analysis showed that this mutant did not make Ψ55 under the conditions of the competition experiment. Therefore, the growth defect due to the lack of TruB must be due to the lack of some other function of the protein, possibly an RNA chaperone activity, but not to the absence of Ψ55.