Fractionation of HeLa cell nuclear extracts reveals minor small nuclear ribonucleoprotein particles

Transcription processing at 1,N2-ethenoguanine by human RNA polymerase II and bacteriophage T7 RNA polymerase

The DNA lesion 1,N(2)-ethenoguanine (1,N(2)-epsilon G) is formed endogenously as a by-product of lipid peroxidation or by reaction with epoxides that result from the metabolism of the industrial pollutant vinyl chloride, a known human carcinogen. DNA replication past 1,N(2)-epsilon G and site-specific mutagenesis studies on mammalian cells have established the highly mutagenic and genotoxic properties of the damaged base. However, there is as yet no information on the processing of this lesion during transcription. Here, we report the results of transcription past a site-specifically modified 1,N(2)-epsilon G DNA template. This lesion contains an exocyclic ring obstructing the Watson-Crick hydrogen-bonding edge of guanine. Our results show that 1,N(2)-epsilon G acts as a partial block to the bacteriophage T7 RNA polymerase (RNAP), which allows nucleotide incorporation in the growing RNA with the selectivity A>G>(C=-1 deletion)>>U. In contrast, 1,N(2)-epsilon G poses an absolute block to human RNAP II elongation, and nucleotide incorporation opposite the lesion is not observed. Computer modeling studies show that the more open active site of T7 RNAP allows lesion bypass when the 1,N(2)-epsilon G adopts the syn-conformation. This orientation places the exocyclic ring in a collision-free empty pocket of the polymerase, and the observed base incorporation preferences are in agreement with hydrogen-bonding possibilities between the incoming nucleotides and the Hoogsteen edge of the lesion. On the other hand, in the more crowded active site of the human RNAP II, the modeling studies show that both syn- and anti-conformations of the 1,N(2)-epsilon G are sterically impermissible. Polymerase stalling is currently believed to trigger the transcription-coupled nucleotide excision repair machinery. Thus, our data suggest that this repair pathway is likely engaged in the clearance of the 1,N(2)-epsilon G from actively transcribed DNA.

Mutation of an RSV intronic element abolishes both U11/U12 snRNP binding and negative regulation of splicing

A cis-acting negative regulator of splicing (NRS) within the gag gene of RSV is involved in control of the relative levels of spliced and unspliced viral mRNAs. Insertion of the NRS into the intron of an adenovirus pre-mRNA resulted in inhibition of splicing in vitro before the first cleavage step. Analyses of spliceosome assembly with this substrate showed that it formed large RNP complexes that did not migrate like mature spliceosomes on native gels. Affinity selection of the RNP complexes formed on NRS-containing pre-mRNAs showed an association with U11 and U12 snRNPs, as well as with the spliceosomal snRNPs. Immunoprecipitation with antisera specific for U1 and U2 snRNPS showed binding of both snRNPs to NRS RNA. A 7-nucleotide missense mutation in the NRS that prevented binding of U11 and U12 snRNPs impaired NRS activity in vivo, suggesting a functional role for U11 and U12 snRNPs in the inhibition of splicing mediated by the RSV NRS RNA.

Sea urchin small RNA ribonucleoprotein particles: identification, synthesis, and subcellular localization during early embryonic development

Small RNAs in sea urchins were examined in order to characterize developmental changes in their level, subcellular localization, synthesis, and association with proteins and other RNAs. Small RNAs such as the U snRNAs, 5S and 5.8S rRNAs, and 7S RNAs were identified by their mobility on highly cross-linked acrylamide gels. In addition, 7SL and U1 RNAs were identified by northern blot hybridization to cloned human and sea urchin probes, respectively. The level, subcellular localization, and association with proteins or RNA do not change for most small RNAs from fertilization to blastula, even though this is the time when the stored maternal pool of many small RNAs is being supplemented and replaced by embryonically synthesized RNAs. New embryonic synthesis of small RNAs was first detected at the 8-12 hr blastula stage. Although the predicted subsets of the total small RNA pool can be found in the appropriate subcellular compartments, newly synthesized small RNAs have a predominantly cytoplasmic localization: All of the newly synthesized small RNAs were found to be constituents of small RNPs. The RNPs containing newly synthesized small RNAs had sedimentation rates indistinguishable from their maternal counterparts. Thus, on the basis of sedimentation rate, no gross differences could be detected between maternal and embryonic small RNP pools. These small RNPs include a cytoplasmic RNP containing newly synthesized U1 snRNA and the sea urchin signal recognition particle (SRP) containing the 7SL, RNA. We have also identified a small RNP bearing the 5S rRNA which is present in both eggs and embryos. The presence of multiple, abundant, small RNAs and RNPs that are maintained at constant levels in particular subcellular fractions throughout development suggests that small RNAs may be involved in many more cellular activities than have so far been described.

Two-step affinity purification of U7 small nuclear ribonucleoprotein particles using complementary biotinylated 2'-O-methyl oligoribonucleotides

U7 snRNP is a low-abundance small nuclear ribonucleoprotein particle essential for 3' processing of replication-dependent histone pre-mRNA. We have developed a two-step purification of the particle from TB21 mouse mastocytoma cell nuclear extracts, with about a 20% overall yield, using affinity binding to 2'-O-methyl oligoribonucleotides. The purified particle is homogeneous with respect to RNA content. SDS/PAGE of the U7 snRNP proteins revealed a full complement of the standard core proteins (B, DD', E, F, and G) found in the majority of snRNPs. In addition, two U7-specific polypeptides of 14 kDa and 50 kDa were identified. Summation of the molecular masses of the identified components of the U7 particle yields a particle mass of 249 kDa, in approximate agreement with estimates from sucrose gradient sedimentation (261 kDa) and nondenaturing gradient PAGE (217 kDa).

Organization and transient expression of the gene for human U11 snRNA

The nucleotide sequence of U11 small nuclear RNA, a minor U RNA from HeLa cells, was determined. Computer analysis of the sequence (135 residues) predicts two strong hairpin loops which are separated by seventeen nucleotides containing an Sm binding site (AAUUUUUUGG). A synthetic gene was constructed in which the coding region of U11 RNA is under the control of a T7 promoter. This vector can be used to produce U11 RNA in vitro. Southern hybridization and PCR analysis of HeLa genomic DNA suggest that U11 RNA is encoded by a single copy gene, and that at least three genomic regions could be U11 RNA pseudogenes. A HeLa genomic copy of a U11 gene was isolated by inverted PCR. This gene contains the U11 RNA coding sequence and several sequence elements unique for the U RNA genes. These include a Distal Sequence Element (DSE, ATTTGCATA) present between positions -215 and -223 relative to the start of transcription; a Proximal Sequence Element (PSE, TTCACCTTTACCAAAAATG) located between positions -43 and -63; and a 3' box (GTTAGGCGAAATATTA) between positions + 150 and + 166. Transfection of HeLa cells with this gene revealed that it is functioning in vivo and can produce U11 RNA.

Immunoprecipitation distinguishes non-overlapping groups of snRNPs in Schizosaccharomyces pombe

The large number of snRNAs in the fission yeast Schizosaccharomyces pombe can be divided into four non-overlapping groups by immunoprecipitation with antibodies directed against mammalian snRNP proteins. 1) Of the abundant snRNAs, anti-Sm sera precipitate only the spliceosomal snRNAs U1, U2, U4, U5 and U6. Surprisingly, three Sm-sera tested distinguish between U2, U4 and U5 and U1 from S.pombe; one precipitating only U1 and two precipitating U2, U4 and U5 but not U1. 2) A group of 11 moderately abundant snRNAs are not detectably precipitated by human anti-Sm sera, but are specifically precipitated by monoclonal antibody H57 specific for the human B/B' polypeptides. From Aspergillus nidulans this antibody also precipitates at least 12 snRNAs. 3) Anti-(U3)RNP sera do not precipitate the above snRNAs, but precipitate at least 6 further snRNAs, including the homologues of U3. Both the anti-(U3)RNP sera and H57 also efficiently precipitate a number of discrete non-capped RNAs. 4) A small number of additional snRNAs are not detectably precipitated by any anti-serum tested to date, further analysis may identify antisera specific for these snRNPs. Western blots of purified snRNP proteins were used to identify the S.pombe proteins responsible for these immunoprecipitations. Several Sm-sera decorate a 16.3kD protein which may be a D protein homologue, monoclonal H57 decorates a further protein of 16kD and an anti-(U3)RNP serum decorates the homologue of the 36kD U3-specific protein, fibrillarin.

Herpesvirus saimiri U RNAs are expressed and assembled into ribonucleoprotein particles in the absence of other viral genes

Marmoset T lymphocytes transformed by herpesvirus saimiri contain a set of five virally encoded U RNAs called HSUR1 through HSUR5. HSUR genes have been individually transfected into a nonlymphoid, nonsimian cell line (HeLa cells) in the absence of any other coding regions of the herpesvirus saimiri genome. The levels of HSUR1 through HSUR4 in HeLa transient-expression systems are comparable to those found in virally transformed T cells (23 to 91%). In contrast, HSUR5 is expressed at ninefold-higher levels in transfected HeLa cells. Immunoprecipitation experiments show that HSURs expressed in transfected cells bind proteins with Sm determinants and acquire a 5' trimethylguanosine cap structure, as they do in transformed T cells. HSUR1 or HSUR4 particles from transfected HeLa cells migrate between 10S and 15S in velocity gradients, identical to the sedimentation of "monoparticles" produced in virally transformed lymphocytes. We conclude from these transfection experiments that no other herpesvirus saimiri or host-cell-specific gene products appear to be required for efficient expression of the HSUR genes or for subsequent assembly of the viral U RNAs into small nuclear ribonucleoprotein particles. In lymphocytes transformed by herpesvirus saimiri, HSUR small nuclear ribonucleoprotein particles are involved in higher-order complexes that sediment between 20S and 25S. HSUR1, HSUR2, and HSUR5 dissociate from such complexes upon incubation at 30 degrees C, whereas the complex containing HSUR4 is stable to incubation.

Schizosaccharomyces U6 genes have a sequence within their introns that matches the B box consensus of tRNA internal promoters

The gene for the U6 small nuclear RNA (snRNA) in the fission yeast Schizosaccharomyces pombe is interrupted by an intron whose structure is similar to those found in messenger RNA precursors (pre-mRNAs) (1). This is the only known example of a split snRNA gene from any organism--animal, plant, or yeast. To address the uniqueness of the S. pombe U6 gene, we have investigated the structures of the U6 genes from five Schizosaccharomyces strains and three other fungi. A fragment of the U6 coding sequence was amplified from the genomic DNA of each strain by the polymerase chain reaction (PCR). The sizes of the PCR products indicated that all of the fission yeast strains possess intron-containing U6 genes; whereas, the U6 genes from the other fungi appeared to be uninterrupted. The sequences of the Schizosaccharomyces U6 gene fragments revealed that each had an intron of approximately 50 base pairs in precisely the same position. In addition to the splice sites and putative branch point regions, a sequence immediately upstream of the branch point consensus was found to be conserved in all of the Schizosaccharomyces U6 genes. This sequence matches the consensus for the B box of eukaryotic tRNA promoters. These results raise the interesting possibility that synthesis of U6 RNA in fission yeast might involve the use of internal promoter elements similar to those found in other genes transcribed by RNA polymerase III.

Nuclear exchange of the U1 and U2 snRNP-specific proteins

The snRNP particles include a set of common core snRNP proteins and snRNP specific proteins. In rodent cells the common core proteins are the B, D, D', E, F and G proteins in a suggested stoichiometry of B2D'2D2EFG. The additional U1- and U2-specific proteins are the 70-kD, A and C proteins and the A' and B" proteins, respectively. Previous cell fractionation and kinetic analysis demonstrated the snRNP core proteins are stored in the cytoplasm in large partially assembled snRNA-free intermediates that assemble with newly synthesized snRNAs during their transient appearance in the cytoplasm (Sauterer, R. A., R. J. Feeney, and G. W. Zieve. 1988. Exp. Cell Res. 176:344-359). This report investigates the assembly and intracellular distribution of the U1 and U2 snRNP-specific proteins. Cell enucleation and aqueous cell fractionation are used to prepare nuclear and cytoplasmic fractions and the U1- and U2-specific proteins are identified by isotopic labeling and immunoprecipitation or by immunoblotting with specific autoimmune antisera. The A, C, and A' proteins are found both assembled into mature nuclear snRNP particles and in unassembled pools in the nucleus that exchange with the assembled snRNP particles. The unassembled proteins leak from isolated nuclei prepared by detergent extraction. The unassembled A' protein sediments at 4S-6S in structures that may be multimers. The 70-kD and B" proteins are fully assembled with snRNP particles which do not leak from isolated nuclei. The kinetic studies suggest that the B" protein assembles with the U2 particle in the cytoplasm before it enters the nucleus.

Four factors are required for 3'-end cleavage of pre-mRNAs

We reported previously that authentic polyadenylation of pre-mRNAs in vitro requires at least two factors: a cleavage/specificity factor (CSF) and a fraction containing nonspecific poly(A) polymerase activity. To study the molecular mechanisms underlying 3' cleavage of pre-mRNAs, we fractionated CSF further and show that it consists of four separable subunits. One of these, called specificity factor (SF; Mr, approximately 290,000), is required for both specific cleavage and for specific polyadenylation and thus appears responsible for the specificity of the reaction. Although SF has not been purified to homogeneity, several lines of evidence suggest that it may not contain an essential RNA component. Two other factors, designated cleavage factors I (CFI; Mr, approximately 130,000) and II (CFII; Mr, approximately 110,000), are sufficient to reconstitute accurate cleavage when mixed with SF. A fourth factor, termed cleavage stimulation factor (CstF; Mr, approximately 200,000), enhances cleavage efficiency significantly when added to a mixture of the three other factors. CFI, CFII, and CstF do not contain RNA components, nor do they affect specific polyadenylation in the absence of cleavage. Although these four factors are necessary and sufficient to reconstitute efficient cleavage of one pre-RNA tested, poly(A) polymerase is also required to cleave several others. A model suggesting how these factors interact with the pre-mRNA and with each other is discussed.

Isolation and sequence of four small nuclear U RNA genes of Trypanosoma brucei subsp. brucei: identification of the U2, U4, and U6 RNA analogs

Trypanosomes use trans splicing to place a common 39-nucleotide spliced-leader sequence on the 5' ends of all of their mRNAs. To identify likely participants in this reaction, we used antiserum directed against the characteristic U RNA 2,2,7-trimethylguanosine (TMG) cap to immunoprecipitate six candidate U RNAs from total trypanosome RNA. Genomic Southern analysis using oligonucleotide probes constructed from partial RNA sequence indicated that the four largest RNAs (A through D) are encoded by single-copy genes that are not closely linked to one another. We have cloned and sequenced these genes, mapped the 5' ends of the encoded RNAs, and identified three of the RNAs as the trypanosome U2, U4, and U6 analogs by virtue of their sequences and structural homologies with the corresponding metazoan U RNAs. The fourth RNA, RNA B (144 nucleotides), was not sufficiently similar to known U RNAs to allow us to propose an identify. Surprisingly, none of these U RNAs contained the consensus Sm antigen-binding site, a feature totally conserved among several classes of U RNAs, including U2 and U4. Similarly, the sequence of the U2 RNA region shown to be involved in pre-mRNA branchpoint recognition in yeast, and exactly conserved in metazoan U2 RNAs, was totally divergent in trypanosomes. Like all other U6 RNAs, trypanosome U6 did not contain a TMG cap and was immunoprecipitated from deproteinized RNA by anti-TMG antibody because of its association with the TMG-capped U4 RNA. These two RNAs contained extensive regions of sequence complementarity which phylogenetically support the secondary-structure model proposed by D. A. Brow and C. Guthrie (Nature [London] 334:213-218, 1988) for the organization of the analogous yeast U4-U6 complex.

Poly(A) polymerase purified from HeLa cell nuclear extract is required for both cleavage and polyadenylation of pre-mRNA in vitro

We have partially purified a poly(A) polymerase (PAP) from HeLa cell nuclear extract which is involved in the 3'-end formation of polyadenylated mRNA. PAP had a molecular weight of approximately 50 to 60 kilodaltons. In the presence of manganese ions, PAP was able to polyadenylate RNA nonspecifically. However, in the presence of magnesium ions PAP required the addition of a cleavage and polyadenylation factor to specifically polyadenylate pre-mRNAs that contain an intact AAUAAA sequence and end at the poly(A) addition site (precleaved RNA substrates). The purified fraction containing PAP was also required in combination with a cleavage and polyadenylation factor and a cleavage factor for the correct cleavage at the poly(A) site of pre-mRNAs. Since the two activities of the PAP fractions, PAP and cleavage activity, could not be separated by extensive purification, we concluded that the two activities are contained in a single component, a PAP that is also required for the specific cleavage preceding the polyadenylation of pre-mRNA.

Isolation and sequence of four small nuclear U RNA genes of Trypanosoma brucei subsp. brucei: identification of the U2, U4, and U6 RNA analogs

Trypanosomes use trans splicing to place a common 39-nucleotide spliced-leader sequence on the 5' ends of all of their mRNAs. To identify likely participants in this reaction, we used antiserum directed against the characteristic U RNA 2,2,7-trimethylguanosine (TMG) cap to immunoprecipitate six candidate U RNAs from total trypanosome RNA. Genomic Southern analysis using oligonucleotide probes constructed from partial RNA sequence indicated that the four largest RNAs (A through D) are encoded by single-copy genes that are not closely linked to one another. We have cloned and sequenced these genes, mapped the 5' ends of the encoded RNAs, and identified three of the RNAs as the trypanosome U2, U4, and U6 analogs by virtue of their sequences and structural homologies with the corresponding metazoan U RNAs. The fourth RNA, RNA B (144 nucleotides), was not sufficiently similar to known U RNAs to allow us to propose an identify. Surprisingly, none of these U RNAs contained the consensus Sm antigen-binding site, a feature totally conserved among several classes of U RNAs, including U2 and U4. Similarly, the sequence of the U2 RNA region shown to be involved in pre-mRNA branchpoint recognition in yeast, and exactly conserved in metazoan U2 RNAs, was totally divergent in trypanosomes. Like all other U6 RNAs, trypanosome U6 did not contain a TMG cap and was immunoprecipitated from deproteinized RNA by anti-TMG antibody because of its association with the TMG-capped U4 RNA. These two RNAs contained extensive regions of sequence complementarity which phylogenetically support the secondary-structure model proposed by D. A. Brow and C. Guthrie (Nature [London] 334:213-218, 1988) for the organization of the analogous yeast U4-U6 complex.

Poly(A) polymerase purified from HeLa cell nuclear extract is required for both cleavage and polyadenylation of pre-mRNA in vitro

We have partially purified a poly(A) polymerase (PAP) from HeLa cell nuclear extract which is involved in the 3'-end formation of polyadenylated mRNA. PAP had a molecular weight of approximately 50 to 60 kilodaltons. In the presence of manganese ions, PAP was able to polyadenylate RNA nonspecifically. However, in the presence of magnesium ions PAP required the addition of a cleavage and polyadenylation factor to specifically polyadenylate pre-mRNAs that contain an intact AAUAAA sequence and end at the poly(A) addition site (precleaved RNA substrates). The purified fraction containing PAP was also required in combination with a cleavage and polyadenylation factor and a cleavage factor for the correct cleavage at the poly(A) site of pre-mRNAs. Since the two activities of the PAP fractions, PAP and cleavage activity, could not be separated by extensive purification, we concluded that the two activities are contained in a single component, a PAP that is also required for the specific cleavage preceding the polyadenylation of pre-mRNA.

Additional low-abundance human small nuclear ribonucleoproteins: U11, U12, etc

Two-dimensional gel fractionation has revealed the existence of a number (greater than or equal to 8) of additional species of HeLa cell small RNAs that have 5' trimethylguanosine cap structures and are bound by proteins containing Sm epitopes. Therefore, these low-abundance (10(3)-10(4) per cell) RNAs belong to the Sm class of small nuclear ribonucleoproteins (snRNPs), whose best-known members are the four highly abundant (approximately 10(6) per cell) particles required for pre-mRNA splicing. The complexity of Sm snRNPs in mammalian cells is thus not greatly different from that previously established for lower eukaryotes. Two of the new RNAs, designated U11 (131 nucleotides) and U12 (150 nucleotides), have been sequenced. The U11 and U12 snRNPs have been characterized further by examining their nuclease sensitivity and their possible interactions with other snRNPs. Potential roles for the low-abundance snRNPs in aspects of pre-mRNA processing are discussed.

Pre-mRNA splicing by complementation with purified human U1, U2, U4/U6 and U5 snRNPs

The four major nucleoplasmic small nuclear ribonucleoprotein particles U1, U2, U4/U6 and U5 can be extensively purified from HeLa cells by immunoaffinity chromatography using a monoclonal anti-trimethylguanosine antibody. The snRNP particles in active splicing extracts are selectively bound to the immunoaffinity matrix, and are then gently eluted by competition with an excess of free nucleoside. Biochemical complementation studies show that the purified snRNPs are active in pre-mRNA splicing, but only in the presence of additional non-snRNP protein factors. All the RNPs that are necessary for splicing can be purified in this manner. The active snRNPs are characterized with respect to their polypeptide composition, and shown to be distinct from several other activities implicated in splicing.

Identification of the human U7 snRNP as one of several factors involved in the 3' end maturation of histone premessenger RNA's

In eukaryotic cells, the conversion of gene transcripts into messenger RNA's involves multiple factors, including the highly abundant small nuclear ribonucleoprotein (snRNP) complexes that mediate the splicing reaction. Separable factors are also required for the 3' end processing of histone pre-mRNA's. The two conserved signals flanking the 3' cleavage site are recognized by discrete components present in active HeLa cell extracts: the upstream stem loop associates with a nuclease-insensitive factor, while binding to the downstream element is mediated by a component having the properties of a snRNP. The sequence of the RNA moiety of the low abundance human U7 snRNP suggests how the relatively degenerate downstream element of mammalian pre-mRNA's could be recognized by RNA base-pairing.

Heat-labile regulatory factor is required for 3' processing of histone precursor mRNAs

In addition to Sm antigen-type small nuclear ribonucleoprotein particle(s) [snRNP(s)], at least one more factor is involved in the in vitro 3' processing of histone precursor mRNAs (pre-mRNAs) in a HeLa cell nuclear extract. This factor can be completely inactivated by mild heat treatment but is resistant to digestion by micrococcal nuclease and is not immunoprecipitated by antisera of the Sm serotype. Both snRNP (the presumed human homologue of the U7 snRNP of the sea urchin) and the heat-labile factor described above show closely similar properties when fractionated on DEAE, heparin, and Mono Q columns. Fractions, after extensive purification, still contain both heat-labile factor and snRNP activity. When analyzed by gel filtration, the heat-labile component distributes bimodally, the smaller component possessing an apparent molecular weight on the order of 40,000, and the larger, of ca. 300,000.