Studies on SP6 promoter using a new plasmid vector that allows gene insertion at the transcription initiation site

Identification of bacteriophage K11 genomic promoters for K11 RNA polymerase

Only one natural promoter that interacts with bacteriophage K11 RNA polymerase has so far been identified. To identify more, in the present study restriction fragments of the phage genome were individually assayed for transcription activity in vitro. The K11 genome was digested with two 4-bp-recognizing restriction enzymes, and the fragments cloned in pUC119 were assayed with purified K11 RNA polymerase. Eight K11 promoterbearing fragments were isolated and sequenced. We report that the nine K11 promoter sequences (including the one previously identified) were highly homologous from -17 to +4, relative to the initiation site at +1. Interestingly, five had -10G and -8A, while the other four had -10A and -8C. The consensus sequences with the natural -10G/-8A and -10A/-8C, and their variants with -10G/-8C and -10A/-8A, showed nearly equal transcription activity, suggesting residues at -10 and -8 do not regulate promoter activity. Using hybridization methods, physical positions of the cloned promoter-bearing sequences were mapped on SalIand KpnI-restriction maps of the K11 genome. The flanking sequences of six cloned K11 promoters were found to be orthologous with T7 or T3 genomic sequences.

Construction of 4-thiouridine site-specifically substituted RNAs for cross-linking studies

Availability of 4-thiouridine (4-thioU)-containing RNAs is the prerequisite for 4-thioU site-specific cross-linking studies. This paper presents a method for constructing such RNAs. A 5'- and a 3'-RNA are synthesized via phage RNA polymerase transcription and/or RNase H site-specific cleavage directed by 2'-O-methyl-RNA-DNA chimeras. These two half-RNAs in combination correspond to the sequence of full-length RNA, with a single nucleotide gap at the junction that will be filled in with a 4-thiouridylate. A single p4SUp, which is derived from 4SUpN (N can be any nucleotide) via 5'-phosphorylation (therefore, the phosphate can be radioactive) followed by RNase A digestion, is then ligated to the 3' end of the 5'-half RNA with T4 RNA ligase. The 3'-phosphate of the ligated product is subsequently removed by calf intestinal alkaline phosphatase to produce a 3'-hydroxyl group. The resulting 5'-half RNA and the 3'-half RNA with a 5'-phosphate group (which can also be radioactive) are then aligned with a bridging deoxyoligonucleotide and ligated with T4 DNA ligase. This method was previously applied to the P120 pre-mRNA that contains an AT-AC intron, yielding three RNAs each containing a single 4-thioU near the 5'-splice site. Subsequent cross-linking studies with these RNAs yielded detailed information regarding interactions between the 5'-splice site and other spliceosomal snRNAs and between the 5'-splice site and proteins during splicing. Because there is no sequence constraint surrounding the site of 4-thioU substitution, this method should be applicable to many other RNAs.

R.SspD5I is a neoschizomer of HphI producing blunt end DNA fragments

The strain Staphylococcus species D5 produces a restriction enzyme. It is the neoschizomer of HphI endonuclease, which cleaves DNA at a distance of eight nucleotides from the recognition sequences producing blunt end DNA fragments: 5'-GGTGA8N /-3' and 3'-CCACT8N /-5'.

The increased level of beta1,4-galactosyltransferase required for lactose biosynthesis is achieved in part by translational control

beta1,4-Galactosyltransferase (beta4GalT-I) participates in both glycoconjugate biosynthesis (ubiquitous activity) and lactose biosynthesis (mammary gland-specific activity). In somatic tissues, transcription of the mammalian beta4GalT-I gene results in a 4.1-kb mRNA and a 3.9-kb mRNA as a consequence of initiation at two start sites separated by approximately 200 bp. In the mammary gland, coincident with the increased beta4GalT-I enzyme level ( approximately 50-fold) required for lactose biosynthesis, there is a switch from the 4.1-kb start site to the preferential use of the 3.9-kb start site, which is governed by a stronger tissue-restricted promoter. The use of the 3.9-kb start site results in a beta4GalT-I transcript in which the 5'- untranslated region (UTR) has been truncated from approximately 175 nt to approximately 28 nt. The 5'-UTR of the 4.1-kb transcript [UTR(4.1)] is predicted to contain extensive secondary structure, a feature previously shown to reduce translational efficiency of an mRNA. In contrast, the 5'-UTR of the 3.9-kb mRNA [UTR(3.9)] lacks extensive secondary structure; thus, this transcript is predicted to be more efficiently translated relative to the 4.1-kb mRNA. To test this prediction, constructs were assembled in which the respective 5'-UTRs were fused to the luciferase-coding sequence and enzyme levels were determined after translation in vitro and in vivo. The luciferase mRNA containing the truncated UTR(3.9) was translated more efficiently both in vitro (approximately 14-fold) and in vivo (3- to 5-fold) relative to the luciferase mRNA containing the UTR(4.1). Consequently, in addition to control at the transcriptional level, beta4GalT-I enzyme levels are further augmented in the lactating mammary gland as a result of translational control.

Transcription of the 5'-terminal cap nucleotide by RNA-dependent DNA polymerase: possible involvement in retroviral reverse transcription

The possible transcription of the 5'-terminal cap nucleotide of mRNA by RNA-dependent DNA polymerase was examined by a single-step assay, based on the generation of a hairpin structure during reverse transcription of globin mRNA. Using this approach, we demonstrated that the 5'-terminal cap nucleotide of mRNA is indeed transcribed by RNA-dependent DNA polymerase into a 3'-terminal residue of cDNA and were able to measure the extent of such transcription. The observed transcription of the cap nucleotide raises a number of questions that may be addressed using the relatively simple single-step assay employed in the present study. Cap nucleotide transcription by RNA-dependent DNA polymerase may have important implications for our understanding of the mechanism of action of reverse transcriptases. It may represent a selection mechanism for only partial transcription of the 5' repeat element of viral RNA genome, thus generating a RNA fragment that may play a role in priming of second (plus) DNA strand during retroviral reverse transcription. Moreover, the demonstrated ability of complementary nucleotides to form hydrogen bonds, even when in a parallel orientation, may have interesting and important consequences.

Evolutionarily conserved elements in the 5' untranslated region of beta globin mRNA mediate site-specific priming of a unique hairpin structure during cDNA synthesis

Generation of double-stranded cDNA during reverse transcription of a variety of mRNA molecules is well known to involve the formation of covalently linked antisense and sense strands in a hairpin configuration. In the present study we have examined the sequence of molecular events which occurs during cDNA synthesis from mouse beta globin mRNA, in particular the self-priming event that initiates synthesis of sense-strand DNA. Upon completion of reverse transcription of globin mRNA and the removal of RNA template by RNase H activity associated with reverse transcriptase, the 3' end of cDNA snaps back to form a stable double-stranded structure, which is extended by reverse transcriptase to generate the sense DNA strand. Surprisingly, the fourteen 3' terminal nucleotides of the beta globin antisense DNA strand (cDNA) have strong complementarity with an internal segment of the same molecule corresponding to a portion of the 5'-untranslated region of the mRNA located just upstream of the translation start site. Efficient second strand cDNA synthesis appears to require the occurrence within the cDNA molecule of these two complementary elements, one of which must be 3'-terminal. A second surprising feature is that the strong complementarity between the terminal and the internal portions of the molecule exists in the antisense DNA and not in the sense mRNA strand. This is because A:C mismatches on the sense strand correspond to relatively stable T:G base pairs on the antisense strand. Such an extended region of complementarity within the segment of cDNA corresponding to the short 5' untranslated region of beta globin mRNA is unlikely to occur purely by chance, suggesting some underlying function. In this regard it is of interest that cDNAs of adult beta globin mRNAs from other mammalian species show a very similar arrangement of complementary elements, and that complementarity is heavily conserved, even when there are substitutions in nucleotide sequence.

Start site selection at lacUV5 promoter affected by the sequence context around the initiation sites

The effects of single base pair substitutions at the initiation sites of lacUV5 promoter on the transcription start site selection by E. coli RNA polymerase were systematically studied. Transcription start sites were mapped by sizing the cytosine-specifically terminated transcripts produced in vitro by using a chain terminator 3'-deoxycytidine 5'-triphosphate (3'-dCTP) in transcription reactions. Transcription of a prototype lacUV5 promoter initiated with three purines (-1G, +1A and +2A; +1 representing the predominant start site) located 6-8 bp downstream from the Pribnow box. All the substitutions affected the start site selection, resulting in a change in the number of start sites (from 3 to 2 or 1) and/or a shift of the major start site (to -1 or +2). None of the variants started outside the 3-bp region and at the positions substituted by a pyrimidine. Purine-to-pyrimidine changes suppressed not only initiation at the substituted position but also, in some cases, at the other purine position. Purine-to-purine changes also shifted the major start site or suppressed the initiation at other sites. Changes at -2 and +5 also affected the start site selection. Thus, the sequence context around the initiation sites of lacUV5 promoter strongly influences the selection of initiating nucleotides by E. coli RNA polymerase.

SP6 RNA polymerase stutters when initiating from an AAA... sequence

The 16S ribosomal RNA gene of Escherichia coli was placed under the transcriptional control of consensus and modified T7 promoters and a modified SP6 promoter. Both T7 and SP6 polymerases faithfully transcribed the coding sequence (beginning at the +1 position) of each construct, although SP6 polymerase was five-fold more effective than T7 polymerase in initiating with the AAAUUG... sequence. An appreciable fraction of the SP6 transcript molecules contained additional adenosines in the -1, -2, -3, -4, and -5 positions. The transcripts containing additional residues constituted approximately 40-50% of the total SP6 transcription products. Neither the nature nor extent of the additional residues was affected by replacing the pppA 5'-end by pA. Since the identity of the inserted residues does not correspond to the sequence of the template, these additional nucleosides must result from 'stuttering' of the SP6 enzyme at the -1 to +3 positions during initiation of transcription.

Infectious RNA transcripts from Ross River virus cDNA clones and the construction and characterization of defined chimeras with Sindbis virus

We have constructed a full-length cDNA clone of the virulent T48 strain of Ross River virus, a member of the alphavirus genus. Infectious RNA can be transcribed from this clone using SP6 or T7 RNA polymerase. The rescued virus has properties indistinguishable from those of the T48 strain of Ross River virus. We have used this clone, together with a full-length cDNA clone of Sindbis virus, to construct chimeric plasmids in which the 5' and the 3' nontranslated regions of the Sindbis and Ross River genomes were exchanged. The nontranslated regions of the two viral genomes differ in both size and sequence although they maintain specific conserved sequence elements. Virus was recovered from all four chimeras. Chimeras containing heterologous 3' nontranslated regions had replicative efficiencies equal to those of the parents. In contrast, the chimeras containing heterologous 5' nontranslated regions were defective in RNA synthesis and virus production, and the severity of the defect was dependent upon the host. Replication of a virus containing a heterologous 5' nontranslated region may be inefficient due to the formation of defective protein-RNA complexes, whereas, the presumptive complexes formed between host or virus proteins and the 3' nontranslated region to promote RNA synthesis appear to function normally in the chimeras.

Specific sequences downstream from -6 are not essential for proper and efficient in vitro utilization of the Escherichia coli lactose promoter

A series of deletion mutants of the wild-type Escherichia coli lactose promoter, with endpoints at +25, +19, +14, +1 and -6 (relative to the start of transcription at +1), was constructed and the deleted DNA replaced with non-lac DNA. These mutants were used to show that no specific DNA sequences downstream from -6 are required for efficient promoter utilization in vitro. In all cases transcription is dependent on the presence of the catabolite activator protein (CAP) and cAMP, and begins at +1 at a level indistinguishable from that at the wild-type promoter. A set of lac DNA fragments deleted to -6 was constructed, having an A, C, G or T residue at +1 and heterologous DNA downstream. These synthetic promoters allow systematic testing of the effect of the initiating nucleotide on the transcription process. Again, transcription occurs mainly from +1, at a level similar to the normal wild-type level. No substantial differences between these promoters are observed in the rates of formation of stable complexes, in the degree of complex formation, in the rate at which polymerase "escapes" from the complex or in abortive transcription products. Equivalent results are seen with a related set of constructs based on the CAP-insensitive lac UV5 promoter. Thus, lac promoter sequences including consensus hexamers at -10 and -35, plus the spacer region between them, provide specificity and efficiency both in initiation of transcription by RNA polymerase and in CAP-polymerase interactions. A question as to whether there is a third RNA polymerase binding site at lac, in addition to the known overlapping P1 and P2 regions, was not unambiguously answered. However, if a "P3" site does exist, it must lie between P1 and P2. Alternatively, the variety of polymerase interactions at wild-type lac may reflect different structural states of the enzyme. The results presented here indicate that DNA downstream from -6 plays little part in determining the conformation of the enzyme at the lactose promoter.

Bacteriophage T4 early promoter regions. Consensus sequences of promoters and ribosome-binding sites

Twenty-nine early promoters from bacteriophage T4 and 14 early promoters from bacteriophage T6 were isolated using vector M13HDL17, a promoterless derivative of M13mp8 carrying a linker sequence, the bacteriophage lambda-terminator tR1, and the lacZ' gene including part of its ribosome-binding site. The consensus sequence for the T4 promoters is: (sequence; see text). Ribosome-binding sites of T4 share the sequence: 5'...g.GGAga..aA.ATGAa.a...3' The consensus sequence of the T4 early promoter regions is significantly different in sequence and length from that of Escherichia coli promoters. Only one of the promoters detected with vector M13HDL17 resembled a typical bacterial promoter. The high information content raises the possibility that additional proteins recognize and contact nucleotides within the promoter region. All T4 early promoters also carry DNA sequences that could support DNA curving, a structural feature that might contribute to promoter recognition.

An efficiently mutagenizable recombinant plasmid for in vitro transcription of the Escherichia coli 16 S RNA gene

The portion of the rrnB operon coding for 16 S RNA was modified to permit efficient in vitro transcription by T7 RNA polymerase of full-length, correctly terminated, biologically active 16 S RNA (W. Krzyzosiak et al., 1987, Biochemistry 26, 2353-2364). The 5'-end of the gene was fused to the class III T7 promoter and the 3'-end was modified so that cleavage with MstII would generate correctly terminated RNA upon runoff transcription. The modified gene was placed in pUC19 by a four-way ligation reaction involving linearized pUC19, a 1490-bp fragment of 16 S rDNA, and two synthetic oligodeoxynucleotides. Because of the cohesive end design, phosphorylation of the synthetic oligomers was not necessary. Single and tandem cassette insertions were used to generate single base changes in the C-1400 region of 16 S RNA. Three examples are described. This method is generally applicable to the 16 S RNA molecule as suitable singlecleavage restriction sites allow all regions to be mutated by this approach.

In vitro transcription and translational efficiency of chimeric SP6 messenger RNAs devoid of 5' vector nucleotides

A plasmid containing the bacteriophage SP6 promoter, designated pHSTO, permits in vitro transcription of RNAs devoid of vector-derived nucleotides. This vector has been characterized for relative transcriptional activity using constructs which alter the conserved nucleotides extending beyond the SP6 transcriptional initiation site. SP6 polymerase efficiently transcribes cDNA inserts which contain a guanosine (G) nucleotide at position +1 relative to the SP6 promoter; however, inserts with an adenosine (A) or pyrimidine at position +1 are not transcribed. Several cellular and viral cDNAs have been transcribed into translatable messenger RNA using this vector; however, SP6 polymerase will not transcribe the A-T rich untranslated leader from alfalfa mosaic virus RNA 4 efficiently unless the viral mRNA cap site is separated from the transcriptional initiation site by twelve base pairs of vector DNA. Chimeric messenger RNAs were created by linking the untranslated leader sequence of several viral mRNAs to the coding region of barley alpha-amylase, and the resultant mRNAs were translated in a wheat germ extract to determine relative translational efficiencies. The untranslated leader sequences of turnip yellow mosaic virus coat protein mRNA and black beetle virus RNA 2 did not increase translational efficiency, while the tobacco mosaic virus leader stimulated translation significantly. The results indicate that substitution of a cognate untranslated leader sequence with a leader derived from a highly efficient mRNA does not necessarily predict enhanced translational efficiency of the chimeric mRNA.

Production of infectious RNA transcripts from Sindbis virus cDNA clones: mapping of lethal mutations, rescue of a temperature-sensitive marker, and in vitro mutagenesis to generate defined mutants

We constructed full-length cDNA clones of Sindbis virus that can be transcribed in vitro by SP6 RNA polymerase to produce infectious genome-length transcripts. Viruses produced from in vitro transcripts are identical to Sindbis virus and show strain-specific phenotypes reflecting the source of RNA used for cDNA synthesis. The cDNA clones were used to confirm the mapping of the causal mutation of ts2 to the capsid protein. A general strategy for mapping Sindbis virus mutations is described and was used to identify two lethal mutations in an original full-length construct which did not produce infectious transcripts. An XbaI linker was inserted in the cDNA clone near the transcriptional start of the subgenomic mRNA; the resulting virus retains the XbaI recognition sequence, thus providing formal evidence that viruses are derived from in vitro transcripts of cDNA clones. The potential applications of the cDNA clones are discussed.

Oligoribonucleotide synthesis using T7 RNA polymerase and synthetic DNA templates

A method is described to synthesize small RNAs of defined length and sequence using T7 RNA polymerase and templates of synthetic DNA which contain the T7 promoter. Partially single stranded templates which are base paired only in the -17 to +1 promoter region are just as active in transcription as linear plasmid DNA. Runoff transcripts initiate at a unique, predictable position, but may have one nucleotide more or less on the 3' terminus. In addition to the full length products, the reactions also yield a large amount of smaller oligoribonucleotides in the range from 2 to 6 nucleotides which appear to be the result of abortive initiation events. Variants in the +1 to +6 region of the promoter are transcribed with reduced efficiency but increase the variety of RNAs which can be made. Transcription reaction conditions have been optimized to allow the synthesis of milligram amounts of virtually any RNA from 12 to 35 nucleotides in length.