SP6 RNA polymerase efficiently synthesizes RNA from short double-stranded DNA templates.

SP6 DNA-dependent RNA polymerase, like T7 RNA polymerase, can be used to synthesize RNA sequences from short DNA templates which contain the 18 base pair promoter region. Use of SP6 polymerase extends the range of possible 5' sequences of RNA products, since the preferred SP6 start site (of the RNA product) is 5'GAAGA, while T7 polymerase prefers 5'GGGAG. The SP6 start site can be advantageous in large-scale syntheses where high concentrations of RNA can lead to aggregation. Using the limited number of DNA templates described here, there appears to be a significant difference between the two enzymes: SP6 polymerase requires a complete duplex DNA substrate for efficient synthesis, unlike the T7 enzyme which works efficiently when only the 18 base promoter region is double-stranded. SP6 polymerase consistently produces higher yields of RNA than does T7 polymerase, and the reactions can be easily scaled up to produce milligram quantities of RNA.     

Strand opening-deficient Escherichia coli RNA polymerase facilitates investigation of closed complexes with promoter DNA: effects of DNA sequence and temperature

Formation of the strand-separated, open complex between RNA polymerase and a promoter involves several intermediates, the first being the closed complex in which the DNA is fully base-paired. This normally short lived complex has been difficult to study. We have used a mutant Escherichia coli RNA polymerase, deficient in promoter DNA melting, and variants of the P(R) promoter of bacteriophage lambda to model the closed complex intermediate at physiologically relevant temperatures. Our results indicate that in the closed complex, RNA polymerase recognizes base pairs as double-stranded DNA even in the region that becomes single-stranded in the open complex. Additionally, a particular base pair in the -35 region engages in an important interaction with the RNA polymerase, and a DNase I-hypersensitive site, pronounced in the promoter DNA of the open complex, was not present. The effect of temperature on closed complex formation was found to be small over the temperature range from 15 to 37 degrees C. This suggests that low temperature complexes of wild type RNA polymerase and promoter DNA may adequately model the closed complex.     

Sequences required for antitermination by phage 82 Q protein

The gene Q antiterminator proteins of phages lambda and 82 modify RNA polymerase at sites (named qut) that are close to, and apparently inseparable from the promoters themselves. Modification occurs while RNA polymerase has paused close to the start site, at nucleotide 16 for lambda, and nucleotides 15 and 25 for phage 82. We present a deletion analysis of the phage 82 qut site that identifies sequences required for pausing and shows that these sequences also are required for efficient Q function in vivo and in vitro. We show (1) that deletions as close as +5 to the RNA start site retain some ability to be modified by Q82, suggesting that part of the qut site is in the non-transcribed region of the promoter; (2) that NusA protein is required for activity of Q82 on certain qut82 site deletions, whereas it only modestly stimulates antitermination from the native qut82 site; and (3) that qut82 is active only on RNA polymerase that initiates at the qut-associated promoter, and not on RNA polymerase that initiates upstream and passes through an otherwise active qut82 site.     

The Respiratory Syncytial Virus Polymerase Has Multiple RNA Synthesis Activities at the Promoter

Respiratory syncytial virus (RSV) is an RNA virus in the Family Paramyxoviridae. Here, the activities performed by the RSV polymerase when it encounters the viral antigenomic promoter were examined. RSV RNA synthesis was reconstituted in vitro using recombinant, isolated polymerase and an RNA oligonucleotide template representing nucleotides 1–25 of the trailer complement (TrC) promoter. The RSV polymerase was found to have two RNA synthesis activities, initiating RNA synthesis from the +3 site on the promoter, and adding a specific sequence of nucleotides to the 3′ end of the TrC RNA using a back-priming mechanism. Examination of viral RNA isolated from RSV infected cells identified RNAs initiated at the +3 site on the TrC promoter, in addition to the expected +1 site, and showed that a significant proportion of antigenome RNAs contained specific nucleotide additions at the 3′ end, demonstrating that the observations made in vitro reflected events that occur during RSV infection. Analysis of the impact of the 3′ terminal extension on promoter activity indicated that it can inhibit RNA synthesis initiation. These findings indicate that RSV polymerase-promoter interactions are more complex than previously thought and suggest that there might be sophisticated mechanisms for regulating promoter activity during infection.     

Initiation of transcription within an RNA-polymerase binding site.

1. The 5'-terminal sequence of the RNA transcribed from bacteriophage fd replicative form DNA under the control of promotor region I has been determined to be ppp(Gp)nUpApApApGpApCpCpUpGpApUpUp. . . 2. This sequence is complementary to the 5'-terminal sequence of the minus strand of the corresponding RNA polymerase binding site I, the starting point for RNA synthesis lying approximately in the middle of the binding site. 3. This initial sequence is also transcribed faithfully from isolated complexes of RNA polymerase and binding site I, obtained by DNase digestion of complexes between RNA polymerase and fd replicative form DNA. These highly stable complexes can not be reconstituted from binding site and enzyme. 4. It is concluded that RNA polymerase binding site and initiation site are identical parts of a promoter region, and that no "drift" between these sites is required as a step in RNA chain initiation. An additional non-transcribed outside region is implicated as essential for full promoter function.