Determination of the RNA binding specificity of the heterogeneous nuclear ribonucleoprotein (hnRNP) H/H'/F/2H9 family.

Members of the heterogeneous nuclear ribonucleoprotein (hnRNP) H protein family, H, H', F, and 2H9, are involved in pre-mRNA processing. We analyzed the assembly of these proteins from splicing extracts onto four RNA regulatory elements as follows: a high affinity hnRNP A1-binding site (WA1), a sequence involved in Rev-dependent export (p17gag INS), an exonic splicing silencer from the beta-tropomyosin gene, and an intronic splicing regulator (downstream control sequence (DCS) from the c-src gene. The entire family binds the WA1, instability (INS), and beta-tropomyosin substrates, and the core-binding site for each is a run of three G residues followed by an A. Transfer of small regions containing this sequence to a substrate lacking hnRNP H binding activity is sufficient to promote binding of all family members. The c-src DCS has been shown to assemble hnRNP H, not hnRNP F, from HeLa cell extracts, and we show that hnRNP 2H9 does not bind this element. The DCS contains five G residues followed by a C. Mutation of the C to an A changes the specificity of the DCS from a substrate that binds only hnRNP H/H' to a binding site for all hnRNP H family members. We conclude that the sequence GGGA is recognized by all hnRNP H family proteins.

Conservation, regulation, synteny, and introns in a large-scale C. briggsae-C. elegans genomic alignment.

A new algorithm, WABA, was developed for doing large-scale alignments between genomic DNA of different species. WABA was used to align 8 million bases of Caenorhabditis briggsae genomic DNA against the entire 97-million-base Caenorhabditis elegans genome. The alignment, including C. briggsae homologs of 154 genetically characterized C. elegans genes and many times this number of largely uncharacterized ORFs, can be browsed and searched on the Web (http://www.cse.ucsc.edu/ approximately kent/intronerator). The alignment confirms that patterns of conservation can be useful in identifying regulatory regions and rarely expressed coding regions. Conserved regulatory elements can be identified inside coding exons by examining the level of divergence at the wobble position of codons. The alignment reveals a bimodal size distribution of syntenic regions. Over 250 introns are present in one species but not the other. The 3' and 5' intron splice sites have more similarity to each other in introns unique to one species than in C. elegans introns as a whole, suggesting a possible mechanism for intron removal.

The allele-specific suppressor sup-39 alters use of cryptic splice sites in Caenorhabditis elegans.

Mutations in the Caenorhabditis elegans sup-39 gene cause allele-specific suppression of the uncoordination defect of unc-73(e936). e936 is a point mutation that changes the canonical G at the 5' end of intron 16 to a U. This mutation activates three splice donors, two of which define introns beginning with the canonical GU. Use of these two cryptic splice sites causes loss of reading frame; interestingly these messages are not substrates for nonsense-mediated decay. The third splice donor, used in 10% of steady-state e936 messages, is the mutated splice donor at the wild-type position, which defines an intron beginning with UU. In the presence of a sup-39 mutation, these same three splice donors are used, but the ratio of messages produced by splicing at these sites changes. The percentage of unc-73(e936) messages containing the wild-type splice junction is increased to 33% with a corresponding increase in the level of UNC-73 protein. This sup-39-induced change was also observed when the e936 mutant intron region was inserted into a heterologous splicing reporter construct transfected into worms. Experiments with splicing reporter constructs showed that the degree of 5' splice site match to the splicing consensus sequence can strongly influence cryptic splice site choice. We propose that mutant SUP-39 is a new type of informational suppressor that alters the use of weak splice donors.

The intronerator: exploring introns and alternative splicing in Caenorhabditis elegans.

The Intronerator (http://www.cse.ucsc.edu/ approximately kent/intronerator/ ) is a set of web-based tools for exploring RNA splicing and gene structure in Caenorhabditis elegans. It includes a display of cDNA alignments with the genomic sequence, a catalog of alternatively spliced genes and a database of introns. The cDNA alignments include >100 000 ESTs and almost 1000 full-length cDNAs. ESTs from embryos and mixed stage animals as well as full-length cDNAs can be compared in the alignment display with each other and with predicted genes. The alt-splicing catalog includes 844 open reading frames for which there is evidence of alternative splicing of pre-mRNA. The intron database includes 28 478 introns, and can be searched for patterns near the splice junctions.

hnRNP A/B proteins are required for inhibition of HIV-1 pre-mRNA splicing.

Splicing of the human immunodeficiency virus type 1 (HIV-1) pre-mRNA must be inefficient to provide a pool of unspliced messages which encode viral proteins and serve as genomes for new virions. Negative cis-regulatory elements (exonic splicing silencers or ESSs) are necessary for HIV-1 splicing inhibition. We demonstrate that heterogeneous nuclear ribonucleoproteins (hnRNPs) of the A and B group are trans-acting factors required for the function of the tat exon 2 ESS. Depletion of hnRNP A/B proteins from HeLa cell nuclear extract activates splicing of tat exon 2 pre-mRNA substrate. Splicing inhibition is restored by addition of recombinant hnRNP A/B proteins to the depleted extract. A high-affinity hnRNP A1-binding sequence can substitute functionally for the ESS in tat exon 2. These results demonstrate that hnRNP A/B proteins are required for repression of HIV-1 splicing.

Specific binding of an exonic splicing enhancer by the pre-mRNA splicing factor SRp55.

Purine-rich exonic splicing enhancers (ESEs) have been identified in many alternatively spliced exons. Alternative splicing of several ESE-containing exons has been shown to depend on subsets of the SR protein family of pre-mRNA splicing factors. In this report, we show that purified SR protein family member SRp55 by itself binds a 30-nt ESE-containing exon, the alternatively spliced exon 5 of avian cardiac troponin T. We show that purified SRp55 binds specifically to this RNA sequence with an apparent Kd of 60 nM as assayed by gel mobility retardation experiments. Mutations in the exon 5 sequence that increase or decrease exon 5 inclusion in vivo and in vitro have correspondingly different affinities for SRp55 in our assays. The exon 5 sequence contains two purine-rich motifs, common to many ESEs, and both are required for SRp55 binding. Hill plot analysis of binding titration reactions indicates that there is a cooperative binding of at least two SRp55 proteins to the exon sequence. Chemical modification interference studies using kethoxal show that SRp55 binding to exon 5 requires the N1 and/or the N2 of almost every G residue in the exon. Dimethylsulfate modification interference studies indicate that none of the N1 positions of A residues in the exon are important for binding. We postulate that SRp55 may recognize both primary sequence and RNA secondary structural elements within pre-mRNA.

A subset of SR proteins activates splicing of the cardiac troponin T alternative exon by direct interactions with an exonic enhancer.

The cardiac troponin T pre-mRNA contains an exonic splicing enhancer that is required for inclusion of the alternative exon 5. Here we show that enhancer activity is exquisitely sensitive to changes in the sequence of a 9-nucleotide motif (GAGGAAGAA) even when its purine content is preserved. A series of mutations that increased or decreased the level of exon inclusion in vivo were used to correlate enhancer strength with RNA-protein interactions in vitro. Analyses involving UV cross-linking and immunoprecipitation indicated that only four (SRp30a, SRp40, SRp55, and SRp75) of six essential splicing factors known as SR proteins bind to the active enhancer RNA. Moreover, purified SRp40 and SRp55 activate splicing of exon 5 when added to a splicing-deficient S100 extract. Purified SRp30b did not stimulate splicing in S100 extracts, which is consistent with its failure to bind the enhancer RNA. In vitro competition of SR protein splicing activity and UV cross-linking demonstrated that the sequence determinants for SR protein binding were precisely coincident with the sequence determinants of enhancer strength. Thus, a subset of SR proteins interacts directly with the exonic enhancer to promote inclusion of a poorly defined alternative exon. Independent regulation of the levels of SR proteins may, therefore, contribute to the developmental regulation of exon inclusion.

Distinct functions of SR proteins in recruitment of U1 small nuclear ribonucleoprotein to alternative 5' splice sites.

Alternative splicing of precursor messenger RNAs (pre-mRNAs) is an important mechanism for the regulation of gene expression. The members of the SR protein family of pre-mRNA splicing factors have distinct functions in promoting alternative splice site usage. Here we show that SR proteins are required for the first step of spliceosome assembly, interaction of the U1 small nuclear ribonucleoprotein complex (U1 snRNP) with the 5' splice site of the pre-mRNA. Further, we find that individual SR proteins have distinct abilities to promote interaction of U1 snRNP with alternative 5' splice junctions. These results suggest that SR proteins direct 5' splice site selection by regulation of U1 snRNP assembly onto the pre-mRNA.

Human SR proteins and isolation of a cDNA encoding SRp75.

SR proteins are a family of proteins that have a common epitope recognized by a monoclonal antibody (MAb104) that binds active sites of polymerase II transcription. Four of the SR family members have been shown to restore activity to an otherwise splicing-deficient extract (S100 extract). Here we show that two untested SR proteins, SRp20 and SRp75, can also complement the splicing-deficient extract. We isolated a cDNA encoding SRp75 and found that this protein, like other SR proteins, contains an N-terminal RNA recognition motif (RRM), a glycine-rich region, an internal region homologous to the RRM, and a long (315-amino-acid) C-terminal domain composed predominantly of alternating serine and arginine residues. The apparent molecular mass of dephosphorylated SRp75 is 57 kDa, the size predicted from the cDNA clone. We also detected mobility shifts after dephosphorylating SRp55, SRp40, SRp30a, and SRp30b; the sizes of the shifts are proportional to the length of the SR domain, suggesting that serines in this domain are phosphorylated.

Distinct functions of SR proteins in alternative pre-mRNA splicing.

Alternative splicing of precursor messenger RNAs (pre-mRNAs) is a common mechanism of regulating gene expression. SR proteins are a family of pre-mRNA splicing factors that are structurally related and evolutionarily conserved. Any member of the SR family can complement a splicing-deficient extract that lacks the entire family of SR proteins. Here it is demonstrated that particular SR proteins have distinct functions in alternative pre-mRNA splicing in vitro. In addition, SR proteins are differentially expressed in a variety of tissues. These results suggest a fundamental role for SR proteins in the regulation of alternative splicing.

SR proteins: a conserved family of pre-mRNA splicing factors.

We demonstrate that four different proteins from calf thymus are able to restore splicing in the same splicing-deficient extract using several different pre-mRNA substrates. These proteins are members of a conserved family of proteins recognized by a monoclonal antibody that binds to active sites of RNA polymerase II transcription. We purified this family of nuclear phosphoproteins to apparent homogeneity by two salt precipitations. The family, called SR proteins for their serine- and arginine-rich carboxy-terminal domains, consists of at least five different proteins with molecular masses of 20, 30, 40, 55, and 75 kD. Microsequencing revealed that they are related but not identical. In four of the family members a repeated protein sequence that encompasses an RNA recognition motif was observed. We discuss the potential role of this highly conserved, functionally related set of proteins in pre-mRNA splicing.

Two members of a conserved family of nuclear phosphoproteins are involved in pre-mRNA splicing.

Monoclonal antibody 104 recognizes a subset of amphibian nuclear granules (B-snurposomes) and active sites of RNA polymerase II transcription in vertebrates and invertebrates. Monoclonal antibody 104 reacts with a set of nuclear serine- and arginine-rich phosphoproteins (SR family) with strikingly conserved apparent molecular masses. The most abundant family members in human (SRp33) and Drosophila (SRp55) cell lines can replace one another as essential splicing factors in a human cell-free system. Each of these polypeptides can functionally replace human SF2, an essential splicing factor that also regulates 5' splice site selection of alternatively spliced pre-mRNAs in vitro. Drosophila SRp55 also functions as an alternative splicing factor in the human cell-free system. Analysis of cloned cDNAs shows that SRp55 and SF2 are highly related and reveals regions of similarity to genetically defined regulators of alternative splicing in Drosophila. These results suggest that the conserved SR family of phosphoproteins, which includes SRp55 and SF2, is involved in constitutive pre-mRNA splicing and in the specificity of alternative splice site selection.

A conserved family of nuclear phosphoproteins localized to sites of polymerase II transcription.

An antibody was identified previously that recognizes sites of polymerase II transcription on lampbrush chromosomes, puffs on polytene chromosomes, and many small granules in the nucleoplasm of all cells tested. This antibody binds a conserved family of phosphorylated polypeptides in vertebrate and invertebrate cells. We developed a method for purifying these proteins that involves differential solubility in MgCl2. We isolated a Drosophila cDNA encoding one of the proteins using information obtained from microsequencing. In vivo expression studies show that this protein is concentrated on sites of polymerase II transcription and that it is highly phosphorylated. The protein shares a high degree of homology with proteins involved in alternative splicing of pre-mRNA suggesting the possibility that this protein plays a role in pre-mRNA splicing.

Inhibition of telomerase by G-quartet DNA structures.

The ends or telomeres of the linear chromosomes of eukaryotes are composed of tandem repeats of short DNA sequences, one strand being rich in guanine (G strand) and the complementary strand in cytosine. Telomere synthesis involves the addition of telomeric repeats to the G strand by telomere terminal transferase (telomerase). Telomeric G-strand DNAs from a variety of organisms adopt compact structures, the most stable of which is explained by the formation of G-quartets. Here we investigate the capacity of the different folded forms of telomeric DNA to serve as primers for the Oxytricha nova telomerase in vitro. Formation of the K(+)-stabilized G-quartet structure in a primer inhibits its use by telomerase. Furthermore, the octanucleotide T4G4, which does not fold, is a better primer than (T4G4)2, which can form a foldback structure. We conclude that telomerase does not require any folding of its DNA primer. Folding of telomeric DNA into G-quartet structures seems to influence the extent of telomere elongation in vitro and might therefore act as a negative regulator of elongation in vivo.

DNA primase and the replication of the telomeres in Oxytricha nova.

An enzymatic activity in crude extracts of macronuclei from the hypotrichous ciliate Oxytricha nova catalyzes the synthesis of RNA consisting of (C4A4)n using an oligodeoxynucleotide template of the telomeric sequence (dG4T4)n. Single-stranded (dG4T4)n is an effective template if it has a random sequence at its 5' end. The enzyme will not use a (dG4T4)n template of any length (up to 64 bases) if it lacks a random sequence at the 5' end. With a random, single-stranded sequence at the 5' end, the (dG4T4)n oligodeoxynucleotide must be at least 36 bases long to work as a template. A 16-base, single-stranded region of (dG4T4)2 is an effective template when joined to a 20-base double-stranded region of (dG4T4)n/(dA4dC4)n, a structural arrangement that is the same as the native telomere of Oxytricha macronuclear DNA. The RNA-synthesizing activity is unaffected by 1.0 mg/ml of alpha-amanitin. Macronuclear extracts have an alpha-amanitin-insensitive, RNA-polymerizing activity that can use a random 55mer oligodeoxynucleotide as a template. This enzyme activity may be the same one that uses (dG4T4)n templates to make (C4A4)n RNA. The (C4A4)n RNA made in the reaction can prime DNA synthesis by the E. coli DNA polymerase I Klenow fragment. Therefore, the RNA polymerase activity fulfills the requirements of the telomere DNA primase that we postulated for replication of telomeres in hypotrichs (Zahler and Prescott, 1988, Nucleic Acids Research 16, 6953-6972).

Telomere terminal transferase activity in the hypotrichous ciliate Oxytricha nova and a model for replication of the ends of linear DNA molecules.

We have found abundant telomere-specific terminal transferase activity in crude macronuclear extracts from vegetatively growing cells of the hypotrichous ciliate Oxytricha nova. This activity adds two to seven tandem repeats of the sequence GGGGTTTT (the Oxytricha telomeric repeat) to the 3' end of oligonucleotide primers ending in repeats of G4T4 and always adds the repeats in the proper phase. The activity requires the presence of micromolar amounts of dGTP and dTTP as well as single-stranded oligomer primers ending 3' with repeats of the Oxytricha telomeric sequence. A nuclease activity is present in the extracts which is closely balanced with telomere terminal transferase activity. We propose a simple model for replication of the ends of linear DNA molecules based on the telomere terminal transferase.