Cloning of the cDNA for U1 small nuclear ribonucleoprotein particle 70K protein from Arabidopsis thaliana.

We cloned and sequenced a plant cDNA that encodes U1 small nuclear ribonucleoprotein (snRNP) 70K protein. The plant U1 snRNP 70K protein cDNA is not full length and lacks the coding region for 68 amino acids in the amino-terminal region as compared to human U1 snRNP 70K protein. Comparison of the deduced amino acid sequence of the plant U1 snRNP 70K protein with the amino acid sequence of animal and yeast U1 snRNP 70K protein showed a high degree of homology. The plant U1 snRNP 70K protein is more closely related to the human counter part than to the yeast 70K protein. The carboxy-terminal half is less well conserved but, like the vertebrate 70K proteins, is rich in charged amino acids. Northern analysis with the RNA isolated from different parts of the plant indicates that the snRNP 70K gene is expressed in all of the parts tested. Southern blotting of genomic DNA using the cDNA indicates that the U1 snRNP 70K protein is coded by a single gene.     

Analysis of genomic clones of the murine U1RNA-associated 70-kDa protein reveals a high evolutionary conservation of the protein between human and mouse

We have isolated and characterised two overlapping lambda EMBL3 clones carrying sequences of the gene for the murine U1RNA-associated 70-kDa protein. The two clones cover around 23 kb of the 70-kDa protein gene including its 3' end. Southern blot hybridisation revealed the existence of a single copy of the 70-kDa protein gene in the mouse genome. The 23-kb-long portion of the 70-kDa protein gene is divided into eight exons. While most of the exons are quite small and are widely scattered throughout the DNA sequence, the last one consists of about 830 bp and encodes 226 amino acids of the 70-kDa protein, including the C-terminus. The predicted amino acid sequence of the region of the 70-kDa protein encoded by the genomic clones reveals high conservation of structure when it is compared with the sequence of the human 70-kDa protein. Interestingly, all deletions, additions and substitutions are localised exclusively within the C-terminus of the protein, accounting for a 5'-3' polarity with respect to protein conservation. Moreover, the analysis of the genomic sequences predicts the existence of multiple subclasses of mRNAs that may arise by alternative pre-mRNA splicing. A 72-bp alternative exon harboring an in-frame termination codon was also found in the mouse 70-kDa gene and shows, surprisingly, 100% nucleotide identity to its human counterpart.     

The human U1-70K snRNP protein: cDNA cloning, chromosomal localization, expression, alternative splicing and RNA-binding.

We have isolated and sequenced cDNA clones encoding the human U1-70K snRNP protein, and have mapped this locus (U1AP1) to human chromosome 19. The gene produces two size classes of RNA, a major 1.7-kb RNA and a minor 3.9-kb RNA. The 1.7-kb species appears to be the functional mRNA; the role of the 3.9-kb RNA, which extends further in the 5' direction, is unclear. The actual size of the hU1-70K protein is probably 52 kd, rather than 70 kd. The protein contains three regions similar to known nucleic acid-binding proteins, and it binds RNA in an in vitro assay. Comparison of the cDNA sequences indicates that there are multiple subclasses of mRNA that arise by alternative pre-mRNA splicing of at least four alternative exon segments. This suggests that multiple forms of the hU1-70K protein may exist, possibly with different functions in vivo.     

Direct, sequence-specific binding of the human U1-70K ribonucleoprotein antigen protein to loop I of U1 small nuclear RNA.

We have studied the interaction of two of the U1 small nuclear ribonucleoprotein (snRNP)-specific proteins, U1-70K and U1-A, with U1 small nuclear RNA (snRNA). The U1-70K protein is a U1-specific RNA-binding protein. Deletion and mutation analyses of a beta-galactosidase/U1-70K partial fusion protein indicated that the central portion of the protein, including the RNP sequence domain, is both necessary and sufficient for specific U1 snRNA binding in vitro. The highly conserved eight-amino-acid RNP consensus sequence was found to be essential for binding. Deletion and mutation analyses of U1 snRNA showed that both the U1-70K fusion protein and the native HeLa U1-70K protein bound directly to loop I of U1 snRNA. Binding was sequence specific, requiring 8 of the 10 bases in the loop. The U1-A snRNP protein also interacted specifically with U1 snRNA, principally with stem-loop II.     

The yeast homolog of the U1 snRNP protein 70K is encoded by the SNP1 gene.

The product of the yeast SNP1 gene has high homology to two domains of the metazoan U1 snRNP protein 70K, which binds to stem/loop I of the U1 RNA. However, the absence of other domains conserved in metazoan 70K and the minimal effect of yeast U1 RNA stem/loop I deletion make the assignment of SNP1 as yeast 70K less clear. To address this question, we have expressed the SNP1 gene as a fusion protein in E. coli and developed a gel shift assay for U1 RNA binding. We show here that the product of the yeast SNP1 gene binds directly and specifically to the first 47 nucleotides of yeast U1 RNA, which include the stem/loop 1 structure. We therefore conclude that the SNP1 gene product is the yeast 70K homolog. This is the first yeast protein to be identified as a homolog of a metazoan snRNP protein.     

Cloning of a yeast U1 snRNP 70K protein homologue: functional conservation of an RNA-binding domain between humans and yeast.

We have cloned and sequenced a gene encoding a yeast homologue of the U1 snRNP 70K protein. The gene, SNP1, encodes a protein which has 30% amino acid identity with the human 70K protein and has a predicted molecular weight of 34 kDa. The yeast and human sequences are more closely related to each other than to other (non-U1) RNA-binding proteins, but diverge considerably in their C-terminal portions. In particular, SNP1 lacks the charged carboxy terminus of the human 70K protein. A yeast strain, a alpha 115, was constructed in which one allele of the SNP1 gene contained a 554 bp deletion. Tetrad analysis of a alpha 115 showed that the SNP1 gene is essential for the viability of yeast cells. The complete human 70K gene did not complement snp1, but the lethal snp1 mutation was rescued by plasmids bearing a chimera in which over half the yeast gene was replaced with the homologous region of the human 70K gene, including the RNA-binding domain. These results suggest that SNP1 encodes a functional homologue of the U1 snRNP 70K protein.     

Cloning and characterization of two processed pseudogenes and the cDNA for the murine U1 snRNP-specific protein C

Genes for the snRNP proteins U1-70K, U1-A, Sm-B′/B, Sm-D1 and Sm-E have been isolated from various metazoan species. The genes for Sm-D1 and Sm-E, which were isolated from a murine and human source respectively, appear to belong to a multigene family. It has been suggested that also for the mammalian U1-C protein such a multigene family exists. With the human U1-C cDNA as a probe, two genes containing sequences homologous to the probe sequence were isolated from a mouse genomic library. Simultaneously, a murine U1-C cDNA was isolated from a mouse cDNA library. This 0.74 kb cDNA contains an open reading frame (ORF) of 477 bp encoding a polypeptide of 159 amino acids (aa) which differs at only one position (position 65) from the human U1-C protein. One of the isolated U1-C genes contains an ORF as well and shares 92% nucleotide sequence identity with the mouse U1-C cDNA. The features of this gene, in particular the absence of introns, the acquisition of a 3′ poly(A) tail and flanking direct repeats, indicate that it represents a processed pseudogene. At the predicted aa sequence level, substitutions of conserved residues at functionally important positions are observed, strongly suggesting that expression of this gene would not lead to a functional polypeptide. The second U1-C gene appeared to be a pseudogene as well because it is also intronless and contains a frameshift mutation compared to the ORF in the mouse U1-C cDNA. The characterization of these two pseudogenes points to the existence of a U1-C multigene family in mice. Furthermore, comparison of aa sequences of the murine, human and Xenopus U1-C shows that the protein is highly conserved through evolution. Since the Xenopus U1-C differs from the two mammalian counterparts solely at a number of positions in the C-terminal region, it can be concluded that aa changes are less well tolerated in the N-terminal region of U1-C than in the rest of the protein.     

Cloning and sequencing of a full length cDNA coding for human retinol-binding protein.

We have isolated and sequenced a cDNA clone coding for human Retinol Binding Protein. The sequence indicates that Retinol Binding Protein is synthesized as a single polypeptide chain precursor which is then matured to the secreted protein by removal of a leader peptide. Southern and Northern blot analysis suggest that the gene is present in one or few copies per haploid genome and is transcribed in a single mRNA species.     

A common RNA recognition motif identified within a defined U1 RNA binding domain of the 70K U1 snRNP protein

We have defined the RNA binding domain of the 70K protein component of the U1 small nuclear ribonucleoprotein to a region of 111 amino acids. This domain encompasses an octamer sequence that has been observed in other proteins associated with RNA, but has not previously been shown to bind directly to a specific RNA sequence. Within the U1 RNA binding domain, an 80 amino acid consensus sequence that is conserved in many presumed RNA binding proteins was discerned. This sequence pattern appears to represent an RNA recognition motif (RRM) characteristic of a distinct family of proteins. By site-directed mutagenesis, we determined that the 70K protein consists of 437 amino acids (52 kd), and found that its aberrant electrophoretic migration is due to a carboxy-terminal charged domain structurally similar to two Drosophila proteins (su(wa) and tra) that may regulate alternative pre-messenger RNA splicing.     

Characterisation of human and murine snRNP proteins by two-dimensional gel electrophoresis and phosphopeptide analysis of U1-specific 70K protein variants.

The proteins of the major human snRNPs U1, U2, U4/U6 and U5 were characterised by two-dimensional electrophoresis, with isoelectric focussing in the first dimension and SDS-polyacrylamide gel electrophoresis in the second. With the exception of protein F, which exhibits an acidic pl value (pl = 3.3), the snRNP proteins are basic. Post-translational modification was found among the proteins associated specifically with the U1 and U2 particles. The most complex modification pattern was observed for the U1-specific 70K protein. This was found in at least 13 isoelectric variants, with pl values ranging from 6.7 to 8.7; these variants differed also in molecular weight. All of the 70K variants are phosphorylated in the cell. Thin-layer analysis of their tryptic phosphopeptides revealed that the 70K variants have four major phosphopeptides in common, in addition to which at least four additional serine residues are phosphorylated to different extents. The comparative phosphopeptide analysis shows that differential phosphorylation alone is not sufficient to explain the occurrence of the many isoelectric variants of 70K, so that the final charge of the 70K variants is determined both by phosphorylation and by other, as yet unidentified posttranslational modifications. By two-dimensional separation of snRNP proteins obtained from mouse Ehrlich ascites tumour cells, it was shown that the pattern of pl values of the mouse proteins was almost identical with the corresponding pattern for human proteins. Even the complex modification patterns of the 70K protein are identical in mouse and man, indicating that the presence in the cell of so many variants of this protein may have functional importance. The major difference between murine and human snRNP proteins is the absence of protein B' from mouse snRNPs. This suggests that the homologous protein B may be able to carry out the task of protein B'.     

Cloning of the human glucocorticoid receptor cDNA.

We show that the human glucocorticoid receptor (GR), isolated from the breast cancer cell line MCF-7, has an apparent molecular weight identical to that of rat liver GR (94 kDa) and reacts with antibodies raised against the latter. These antibodies were used to clone cDNA sequences corresponding to the human GR from a lambda gt11 expression library constructed using MCF-7 poly(A)+ RNA. Three non-homologous cDNA clones with inserts of 125, 220 and 350 bp, which express epitopes recognised by the rat liver GR antibodies, were isolated. Rat liver GR antibodies, immunopurified using the immobilised purified beta-galactosidase fusion proteins, detect partially purified rat liver and human GRs on Western blots. In addition, these antibodies immuno-adsorb rat liver and human GRs affinity-labelled with [3H] triamcinolone acetonide. Northern blot analysis, using all three cDNA probes, reveals the presence of a major MCF-7 poly(A)+ RNA species of approximately 7 kb.     

Cloning and expression of the cDNA for human antithrombin III.

A partial cDNA clone for human antithrombin III (ATIII) was obtained by screening a cDNA library prepared from size fractionated liver RNA with a pool of eight 16-base long synthetic DNA fragments whose sequence was determined from protein sequence data. A fragment of the partial cDNA clone was used to enrich RNA for ATIII messages, and cDNA clones encoding the entire ATIII structural gene were identified. The complete nucleotide and predicted amino acid sequences of human ATIII and its 32 residue signal peptide are reported, and provide further opportunity to compare the ATIII primary structure with corresponding regions from homologous proteins, alpha 1-antitrypsin and ovalbumin. Plasmids in which the structural genes for mature and pre-ATIII were linked to the E. coli trp promoter-operator support the synthesis of human antithrombin III and pre-antithrombin III in bacteria.     

Cloning of the cDNA of a human neutrophil bactericidal protein. Structural and functional correlations

The bactericidal permeability increasing protein (BPI) is a 50-60-kDa membrane-associated protein isolated from granules of polymorphonuclear leukocytes. A full-length cDNA clone encoding human BPI has been isolated and the derived amino acid sequence reveals a structure that is consistent with previously determined biological properties. BPI may be organized into two domains: the amino-terminal half, previously shown to contain all known antimicrobial activity, contains a large fraction of basic and hydrophilic residues. In contrast, the carboxyl-terminal half contains more acidic than basic residues and includes several potential transmembrane regions which may anchor the holoprotein in the granule membrane. The cytotoxic action of BPI is limited to many species of Gram-negative bacteria; this specificity may be explained by a strong affinity of the very basic aminoterminal half for the negatively charged lipopolysaccharides that are unique to the Gram-negative bacterial envelope. The amino-terminal end of BPI exhibits significant similarity with the sequence of a rabbit lipopolysaccharide-binding protein, suggesting that both molecules share a similar structure for binding lipopolysaccharides.     

Homodimerization of the human U1 snRNP-specific protein C.

The U1 snRNP-specific protein C contains an N-terminal zinc finger-like CH motif which is required for the binding of the U1C protein to the U1 snRNP particle. Recently a similar motif was reported to be essential for in vivo homodimerization of the yeast splicing factor PRP9. In the present study we demonstrate that the human U1C protein is able to form homodimers as well. U1C homodimers are found when (i) the human U1C protein is expressed in Escherichia coli, (ii) immunoprecipitations with anti-U1C antibodies are performed on in vitro translated U1C, and when (iii) the yeast two hybrid system is used. Analyses of mutant U1C proteins in an in vitro dimerization assay and the yeast two hybrid system revealed that amino acids within the CH motif, i.e. between positions 22 and 30, are required for homodimerization.