Regulation of p53 expression by thymidylate synthase.

Previous studies showed that thymidylate synthase (TS), as an RNA binding protein, regulates its own synthesis by impairing the translation of TS mRNA. In this report, we present evidence that p53 expression is affected in a similar manner by TS. For these studies, we used a TS-depleted human colon cancer HCT-C cell that had been transfected with either the human TS cDNA or the Escherichia coli TS gene. The level of p53 protein in transfected cells overexpressing human TS was significantly reduced when compared with its corresponding parent HCT-C cells. This suppression of p53 expression was the direct result of decreased translational efficiency of p53 mRNA. Similar results were obtained upon transfection of HCT-C cells with pcDNA 3.1 (+) containing the E. coli TS gene. These findings provide evidence that TS, from diverse species, specifically regulates p53 expression at the translational level. In addition, TS-overexpressing cells with suppressed levels of p53 are significantly impaired in their ability to arrest in G1 phase in response to exposure to a DNA-damaging agent such as gamma-irradiation. These studies provide support for the in vivo biological relevance of the interaction between TS and p53 mRNA and identify a molecular pathway for controlling p53 expression.

High-level expression of human thymidylate synthase.

A method is presented for expressing human thymidylate synthase (TS) to the extent of 25-30% of the protein in Escherichia coli. By this procedure, 200-400 mg of pure enzyme can be obtained from a 2-liter culture of cells. The key to the level of expression appears to be related to the conversion of purine bases in the third, fourth, and fifth codons of the TS cDNA to thymine, without altering the encoded protein product. Conversion of the penultimate proline to a leucine did not diminish expression, but while the isolated native enzyme contained only proline on its amino-terminal end, the mutated enzyme was found to contain methionine on its amino terminus. By contrast, the expression of the unmodified TS cDNA represented only about 0.1-0.2% of the total cellular protein. Unlike recombinant rat and human TSs, the respective enzymes purified to homogeneity from eukaryotic cells were blocked at the amino ends and possessed 2- to 4-fold lower specific activities. To determine at what level the impairment of expression occurred, an in vitro transcription, translation system was employed and the results showed that while transcription was unaffected, the translation of native TS mRNA was reduced by at least 20-fold relative to modified TS mRNA using a rabbit reticulocyte translation system. Thus, it appears that at least for the TS gene, expression is greatly influenced by the GC content of the 5' coding region of the gene in both prokaryote and eukaryote systems.

Complete restoration of activity to inactive mutants of Escherichia coli thymidylate synthase: evidence that E. coli thymidylate synthase is a half-the-sites activity enzyme.

Escherichia coli thymidylate synthase (TS) is a dimeric protein containing identical subunits. When R126E, an inactive mutant of this enzyme, was incubated at room temperature with other inactive mutants of E. coli, TS enzyme activity gradually reappeared. The rate of activity restoration was dependent on the mutant employed. In the case of C146W, an active site mutant, the half-time required for maximal activity restoration was about one hour, which was about 500-fold faster than that obtained with C146S. The final specific activity of the mutant mixtures, based on the concentration of R126E, was equivalent to that of the wild-type TS (WT-TS). However, when the activities of E. coli WT-TS and mutant TS mixtures were compared for their extents of renaturation following denaturation as described for Lactobacillus casei TS [Pookanjanatavip, M., Yuthavong, Y., Greene, P. J., & Santi, D. V. (1992) Biochemistry 31, 10303-10309], only about one-half of the activity of WT-TS was restored, implying that the denaturation-renaturation procedure was less efficient than allowing the native TS mutant dimers to exchange subunits. If, as proposed, subunit exchange is responsible for the observed restoration of activity to the E. coli mutant TS mixtures, it would suggest that only one active site cysteine, that provided by R126E in the dimer (R126E)-(C146W), is sufficient to yield the same kcat as WT-TS, which contains one active site cysteine in each subunit. Other mutant dimers that contain both active site cysteines such as (R126E)-(Y94A) and (R126E)-(I264Am) are also fully active, even though one of the subunits is functionally inactive.(ABSTRACT TRUNCATED AT 250 WORDS)

Catalytically active cross-species heterodimers of thymidylate synthase.

Thymidylate synthase (TS) is a highly conserved homodimeric enzyme with two active sites, each of which contains amino acid residues from both subunits. We show that the conservation at the subunit interface between Escherichia coli TS and Lactobacillus casei TS is sufficient to permit the formation of a cross-species heterodimer between subunits of E. coli TS and L. casei TS. Heterodimer formation was monitored by the generation of catalytic activity when combinations of inactive E. coli homodimers and inactive L. casei homodimers were mixed under conditions of reversible unfolding and dissociation. The inactive L. casei mutant enzymes (Lc)C198A, (Lc)C198L, and (Lc)V316Am were tested as Arg donors to the active sites of the inactive E. coli mutant enzymes (Ec)R126Q and (Ec)R126E, while the inactive E. coli mutant enzymes (Ec)K48Q, (Ec)C146S, (Ec)R166Q, and (Ec)I264Am were tested as Arg donors to the active site of inactive (Lc)R178F. Except for (Lc)V316Am, all of the mutant enzymes tested were able to form catalytically active cross-species heterodimers. (Lc)C198A and (Ec)R126Q were cotransformed on compatible plasmids into a thymine-requiring E. coli host, and this combination was able to form sufficient active TS in vivo to support growth. Titration of (Ec)R126Q with (Lc)C198A showed that the cross-species heterodimer formed with the same probability as the intraspecies homodimers in the refolding mixture. The single active site formed by this pair has kcat and Km values similar to those of an intraspecies heterodimer.

Purification and substrate specificity of a T4 phage intron-encoded endonuclease.

The T4 phage td intron-encoded endonuclease (I-Tev I) cleaves the intron-deleted td gene (td delta I) 23 nucleotides upstream of the intron insertion site on the noncoding strand and 25 nucleotides upstream of this site on the coding strand, to generate a 2-base hydroxyl overhang in the 3' end of each DNA strand. I-Tev I-157, a truncated form in which slightly more than one third (88 residues) of the endonuclease is deleted, was purified to homogeneity and shown to possess endonuclease activity similar to that of I-TEV I, the full-length enzyme (245 residues). The minimal length of the td delta I gene that was cleaved by I-Tev I and I-Tev I-157 has been determined to be exactly 39 basepairs, from -27 (upstream in exon1) to +12 (downstream in exon2) relative to the intron insertion site. Similar to the full-length endonuclease, I-Tev I-157 cuts the intronless thymidylate synthase genes from such diverse organisms as Escherichia coli, Lactobacillus casei and the human. The position and nature of the in vitro endonucleolytic cut in these genes are homologous to those in td delta I. Point mutational analysis of the td delta I substrate based on the deduced consensus nucleotide sequence has revealed a very low degree of specificity on either side of the cleavage site, for both the full-length and truncated I-TEV I.

Characterization of the restriction site of a prokaryotic intron-encoded endonuclease.

The 1016-base-pair (bp) intron in the T4 bacteriophage thymidylate synthase gene (td) contains a 735-bp open reading frame that encodes a protein product with endonucleolytic activity. The endonuclease shows specificity for the intronless form of the td gene. Highly purified endonuclease cleaves the DNA of the intronless form of the td gene in vitro at 24 bp upstream of the exon 1-exon 2 junction, generating a 2-base staggered cut with 3'-hydroxyl overhangs. Although the endonuclease cleaves in exon 1, it requires some exon 2 sequence for recognition. The maximum recognition sequence lies in an 87-bp stretch, from 52 bp upstream to 35 bp downstream of the cleavage site, ending at 11 bp into exon 2. The td intron endonuclease appears involved in the conversion of the intronless form of td to intron-containing td gene in the T-even phages. A role for intron mobility is discussed.

Structural conservation among three homologous introns of bacteriophage T4 and the group I introns of eukaryotes.

Three group I introns of bacteriophage T4 have been compared with respect to their sequence and structural properties. The introns include the td intervening sequence, as well as the two newly described introns in the nrdB and sunY genes of T4. The T4 introns are very closely related, containing phylogenetically conserved sequence elements that allow them to be folded into a core structure that is characteristic of eukaryotic group IA introns. Similarities extend outward to the exon sequences surrounding the three introns. All three introns contain open reading frames (ORFs). Although the intron ORFs are not homologous and occur at different positions, all three ORFs are looped-out of the structure models, with only the 3' ends of each of the ORFs extending into the secondary structure. This arrangement invites interesting speculations on the regulation of splicing by translation. The high degree of similarity between the T4 introns and the eukaryotic group I introns must reflect a common ancestry, resulting either from vertical acquisition of a primordial RNA element or from horizontal transfer.

Variable occurrence of the nrdB intron in the T-even phages suggests intron mobility.

The bacteriophage T4 nrdB gene, encoding nucleoside diphosphate reductase subunit B, contains a self-splicing group I intervening sequence. The nrdB intron was shown to be absent from the genomes of the closely related T-even phages T2 and T6. Evidence for variable intron distribution was provided by autocatalytic 32P-guanosine 5'-triphosphate labeling of T-even RNAs, DNA and RNA hybridization analyses, and DNA sequencing studies. The results indicate the nonessential nature of the intron in nrdB expression and phage viability. Furthermore, they suggest that either precise intron loss from T2 and T6 or lateral intron acquisition by T4 occurred since the evolution of these phages from a common ancestor. Intron movement in the course of T-even phage divergence raises provocative questions about the origin of these self-splicing elements in prokaryotes.

Two domains for splicing in the intron of the phage T4 thymidylate synthase (td) gene established by nondirected mutagenesis.

Of 97 nondirected T4 thymidylate synthase-defective (td) mutations, 27 were mapped to the intron of the split td gene. Clustering of these intron mutations defined two domains that are functional in splicing, each within approximately 220 residues of the respective splice sites. Two selected mutations, tdN57 and tdN47, fell within phylogenetically conserved pairings, with tdN57 disrupting the exon I-internal guide pairing (P1) in the 5' domain and tdN47 destabilizing the P9 helix in the 3' domain. A splicing assay with synthetic oligonucleotides complementary to RNA junction sequences revealed processing defects for T4tdN57 and T4tdN47, both of which are impaired in cleavage at the 5' and 3' splice sites. Thus prokaryotic genetics facilitates association of specific residue changes with their consequences to splicing.

Processing of phage T4 td-encoded RNA is analogous to the eukaryotic group I splicing pathway.

Several features of the split td gene of phage T4 suggest an RNA processing mechanism analogous to that of the self-splicing rRNA of Tetrahymena and other group I eukaryotic introns. Previous work has revealed conserved sequence elements and the ability of td-encoded RNA to self-splice in vitro. We show here that a noncoded guanosine residue is covalently joined to the 5' end of the intron during processing. Further, we demonstrate the existence of linear and circular intron forms in RNA extracted from T4-infected cells and from uninfected Escherichia coli expressing the cloned td gene. Sequence analysis of the intron cyclization junction indicates that the noncoded guanosine and one additional nucleotide are lost from the 5' end of the intron upon cyclization. This analysis places a uridine residue upstream of the cyclization site, in analogy to three other group I cyclization junctions. These striking similarities to the splicing intermediates of eukaryotic group I introns point not only to an analogous processing pathway and conserved features of cyclization site recognition but also to a common ancestry between this prokaryotic intervening sequence and the group I eukaryotic introns.

RNA splicing and in vivo expression of the intron-containing td gene of bacteriophage T4.

The splice junction sequence of td mRNA from T4-infected cells has been determined (5'....GGU-CUA....3') and shown to be identical to that of the RNA ligation product encoded by the cloned gene [Belfort et al. Cell 41 (1985) 375-382]. The RNA processing functions, T4 RNA ligase, T4 polynucleotide kinase, and the host prr gene product appear not to be essential for exon ligation; neither are the host endoribonucleases RNase III, RNase P and RNase E required for intron excision. While these results are consistent with the autocatalytic splicing mechanism demonstrated in vitro [Chu et al. J. Biol. Chem. 260 (1985) 10680-10688], they leave unanswered the question of which protein(s), if any, might stimulate the in vivo reaction. Analysis of the products of the cloned td gene has led to identification of two td-encoded polypeptides, namely a polypeptide corresponding to the exon-I-coding sequence (NH2-TS), and the catalytically active thymidylate synthase (TS). Kinetic and nucleotide sequence data provide evidence that NH2-TS is the product of the primary transcript and that TS is encoded by spliced mRNA. These results suggest that splicing may provide a switch controlling the relative expression of NH2-TS and TS, two proteins with markedly different temporal appearances despite their identical transcriptional and translational start sites.

Processing of the intron-containing thymidylate synthase (td) gene of phage T4 is at the RNA level.

The interrupted T4 phage td gene, which encodes thymidylate synthase, is the first known example of an intron-containing prokaryotic structural gene. Analysis of td-encoded transcripts provides evidence in favor of maturation at the RNA level. Northern blotting with T4 RNA and with region-specific probes revealed three classes of RNA: diffuse premessage (ca. 2.5 kb), a low-abundance mature mRNA (ca. 1.3 kb), and an abundant free intron RNA (ca. 1.0 kb). The existence of covalently joined mature mRNA was suggested by hybridization and S1 protection experiments and was confirmed by primer extension analysis of the splice junction. In analogy to expression of interrupted eukaryotic genes, these results are consistent with an RNA processing model that would account for the direct gene transcript serving as precursor for both free intron RNA and a spliced mRNA that is colinear with the thymidylate synthase product.

Genetic system for analyzing Escherichia coli thymidylate synthase.

Random in vitro mutagenesis of the thyA gene is being used to delineate its regulatory elements as well as the functional domains of its product, thymidylate synthase (EC 2.1.1.45). Streamlined procedures have been developed for the isolation and characterization of the mutants. Positive selection for synthase-deficient thyA Escherichia coli permitted the isolation of 400 mutants, which are being categorized by phenotypic and genetic criteria. An in situ 5-fluorodeoxyuridylate binding assay was devised to rapidly probe the substrate binding domain, whereas facile mapping procedures, based on pBR322- or M13-borne thyA deletion derivatives, were developed to localize mutations. The sequence changes of one amber mutation and another mutation that abolishes catalysis while maintaining substrate binding activity are presented. The orientation of the thyA gene on the E. coli chromosome was established.

Primary structure of the Escherichia coli thyA gene and its thymidylate synthase product.

The nucleotide sequence of a 1,163-base-pair fragment that encodes the entire thyA gene of Escherichia coli K-12 was determined. The strategy involved sequence determination of both DNA strands by using overlapping deletions that had been generated in vitro from the two ends of the fragment with BAL-31 nuclease. The amino-terminal sequence of thymidylate synthase (5,10-methylenetetrahydrofolate:dUMP C-methyltransferase, EC 2.1.1.45), the product of the thyA gene, located the 792-base-pair open reading frame, which codes for the 264 amino acid residues of this enzyme. The amino acid sequence deduced from the nucleotide data was confirmed to the extent of 40% by partial sequence analysis of the enzyme purified from extracts of the amplified cloned gene. Transcriptional and translational control areas were apparent in the regions flanking the structural gene. The 5-fluorodeoxyuridylate-binding residue of the active site was identified as cysteine-146. Comparison of the E. coli and Lactobacillus casei synthase sequences reveals consistent homology (62%) over extensive regions. This homology is particularly striking in a very hydrophobic region bordering cysteine-146. In the two enzymes, this region, which probably defines the active site, is 82% homologous. However, a dramatic difference between the two sequences is reflected by the surprising finding that a 51-amino-acid stretch, present midway through the L. casei sequence, is completely absent from the E. coli enzyme.