©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
Abortive Initiation and First Bond Formation at an Activated Adenovirus E4 Promoter (*)

(Received for publication, July 13, 1995; and in revised form, September 11, 1995)

Ying Jiang (§) Ming Yan (§) Jay D. Gralla (¶)

From the Department of Chemistry and Biochemistry and the Molecular Biology Institute, University of California, Los Angeles, California 90095-1569

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Abortive initiation at the adenovirus E4 promoter was studied by following the production of RNA formed from the initiating nucleotides UpA and CTP. Formation of a specific short RNA via a reaction with appropriate alpha-amanitin sensitivity required promoter, activator, and ATP. In the absence of any of these, an alpha-amanitin-resistant reaction led to lower levels of a product of unknown origin. The alpha-amanitin-sensitive reaction required open promoter complexes, as assayed directly by permanganate probing. This reaction was not blocked by the inhibition of polymerase C-terminal domain kinase activity or by the lack of DNA supercoiling. Thus, formation of the initial bond of the mRNA appears to require activator and ATP to open the DNA but not phosphorylation of the polymerase C-terminal domain. In addition, the abortive initiation reaction was strongly suppressed when all elongation substrates were present, suggesting that cycling to produce high amounts of abortive product is strongly disfavored during productive initiation at this promoter.


INTRODUCTION

The mechanism by which RNA polymerase II makes the initial bonds of the mRNA and clears the promoter is not well understood. Recent studies have suggested that a number of factors may influence this process. These include the general factors TFIIH, TFIIE, and TFIIF, which may have components that act primarily at these steps (Parvin et al., 1992; Parvin and Sharp, 1993; Chang et al., 1993; Goodrich and Tjian, 1994). In addition, the overall process requires ATP, independent of the use of ATP as an elongation substrate (Bunick et al., 1982; Sawadogo and Roeder, 1984; Conaway and Conaway, 1988; Jiang et al., 1993). The ATP involvement could be at any of several substeps, including opening the DNA template (Wang et al., 1992a; Jiang et al., 1993), phosphorylating the C-terminal domain (CTD) (^1)of the polymerase (reviewed by Corden(1990) and Young(1991)), and supporting the helicase activity of TFIIH (Schaeffer et al., 1993; Serizawa et al., 1993b). Each of these activities relies on the hydrolysis of the beta- bond of ATP, and therefore dATP can act as a substitute. These issues have assumed greater relevance with the emergence of studies, suggesting that some activators may work by facilitating promoter clearance or assisting the resumption of transcription by stalled polymerases (Parada et al., 1995; Narayan et al., 1994; Krumm et al., 1995; Lee and Gilman, 1994; Rasmussen and Lis, 1993; Yankulov et al., 1994).

A critical step in this overall process is the formation of the first bond of the mRNA. This step has been studied using abortive initiation assays (Luse and Jacob, 1987; Jacob et al., 1991, 1994; Goodrich and Tjian, 1994) based on an analogous reaction used for prokaryotic transcription studies (McClure et al., 1978; Carpousis and Gralla, 1980). In these assays the formation of the first bond is monitored via condensation of a dinucleotide primer and the next encoded nucleoside triphosphate of the transcript. Such reactions appear to properly mimic initiation in the sense that maximal accumulation of the trinucleotide product requires an intact promoter, the dinucleotide primer, nucleoside triphosphate, and an in vitro transcription system in which all components are active. Because the trinucleotide product can in principle be made in very large excess over the amount of template present, the assay allows high detectability even from very inefficient systems.

The specificity of this abortive initiation assay has been established, but the requirements for forming the abortive initiation product are yet to be established. Luse and Jacob(1987) suggested that the reaction at the adenovirus major late promoter used ATP beta- bond hydrolysis, based on the ability of dATP to stimulate production of trinucleotide. This early work pre-dates the studies showing roles for ATP hydrolysis in promoter opening (Wang et al., 1992a), in phosphorylating the polymerase CTD (Cadena and Dahmus(1987); reviewed by Corden(1990) and Young(1991)), and in generic promoter clearance (Goodrich and Tjian, 1994), and thus no mechanistic role was proposed. A later study using purified components confirmed the specificity of the abortive initiation reaction at this promoter (Goodrich and Tjian, 1994) but suggested that ATP was not involved in the steps leading up to and including formation of the first bond of the mRNA. Instead it was suggested that ATP hydrolysis was required for the subsequent steps of promoter clearance, perhaps via an activity associated with factor TFIIH.

Thus the requirements for formation of the first mRNA bond and for transcription initiation are unsettled and need further clarification. This is especially true with regard to the various critical steps that use ATP because of its proposed role in three activities: the opening of the DNA and two activities associated with TFIIH. The latter activities are phosphorylation of the polymerase CTD (factor TFIIK) (Feaver et al., 1994; Svejstrup et al., 1995) and DNA helicase activity (Schaeffer et al., 1993; Serizawa et al., 1993b). Each of these three activities has an unknown relationship to forming the first bond of the transcript; thus the role of ATP in first bond formation is especially unclear. An additional unsettled issue relates to the amount of abortive initiation that occurs as a byproduct of productive initiation. Abortive initiation products have been detected under conditions where they could in principle be elongated via nucleotide addition. This is most easily detected at certain promoters greatly weakened by mutation (Jacob et al., 1991, 1994). The extent to which abortive initiation is suppressed during normal, productive initiation at wild type promoters is uncertain.

We address these issues by studying abortive initiation at an activated adenovirus E4 promoter. Recently we proposed that initiation at this promoter involves two successive steps that hydrolyze ATP. (^2)In the first step ATP is used to open the DNA, and in a later step it is used to phosphorylate the polymerase CTD, stimulating the ability of the polymerase to move downstream during initiation. In this scheme the formation of the first bond of the mRNA would require the first of these ATP-dependent steps but perhaps would not require the second step. The results of these experiments will define the requirements for first bond formation at this promoter and will help to integrate abortive initiation and promoter clearance studies, allowing more general models to be proposed and tested.


MATERIALS AND METHODS

High pressure liquid chromatography-purified ribonucleoside triphosphates and deoxyribonucleoside triphosphates were from Pharmacia Biotech Inc. Sepharose CL-4B and alpha-amanitin were from Sigma. The CTD kinase inhibitor H8 (N-(2-(methylamino)ethyl)-5-isoquinoline sulfonamide dihydrochloride) was from Seikagaku American Inc. Nuclear extract was prepared as described previously (Dignam et al., 1983). The DNA template contains nine GAL4 binding sites upstream of a truncated adenovirus E4 promoter (Carey et al., 1990).

RNA polymerase II preinitiation complexes were enriched as described previously (Laybourn and Dahmus, 1990; Carey et al., 1986) with modifications as indicated. First, a transcription mixture of 400 µl was set up that contained 250 µl of Hela nuclear extract (protein concentration of 6 mg/ml in D buffer (20 mM Hepes, pH 7.9, 100 mM KCI, 0.1 mM EDTA, 20% glycerol, 1 mM dithiothreitol, 1 mM phenylmethylsulfonyl fluoride)), 8.25 mM magnesium chloride, 100-300 ng supercoiled template with or without activator GAL4-AH. This was incubated at 30 °C for 30 min to allow the assembly of preinitiation complexes and then loaded on a 6-ml Sepharose CL-4B column equilibrated with times D buffer with 8 mM magnesium. The column was eluted with the same solution at room temperature in approximately 15 min. DNA elutes in the void volume, which was detected by blue dextran (molecular mass, 2 MDa). This was verified by running fractions on an agarose gel. The enriched preinitiation complexes (typically 0.5 ml) were used immediately.

The abortive initiation assay used dinucleotide primer UpA (2 mM) and the next templated nucleotide CTP (1 µM) ,which is alpha-P-radiolabeled. When present, dATP (10 µM) or alpha-amanitin (1 µg/ml) or 2 mM H8 was added before the addition of UpA and CTP. Standard reactions involved 20 µl of column fraction with added nucleotides for 15 min at 30 °C. At this time the reaction was stopped by adding 20 µl of formamide/8 M urea, and the sample was loaded directly on to a 25% polyacrylamide/8 M urea gel (Carpousis and Gralla, 1980).

The time course and interference experiments began with the addition of UpA, CTP, and dATP. The reactions were stopped at various times, and UpApC was assayed as described above. In the alpha-amanitin interference experiment, alpha-amanitin was added at 5 min, and the reaction was stopped at 10 min. The elongation substrates interference experiment used a similar protocol except the three elongation substrates were added (GTP and UTP to 25 µM; AMPPNP to 10 µM) instead of alpha-amanitin.


RESULTS

This study involves abortive initiation at an activated version of the adenovirus E4 promoter. Previously, conditions were established for studying productive transcription and open complex formation at this promoter (Carey et al., 1990; Wang et al., 1992a, 1992b; Jiang and Gralla, 1993). The promoter contains a TATA box as a basal element and has upstream sites for the binding of a GAL4-AH hybrid transcription activator. Preinitiation complexes are assembled by mixing a supercoiled template containing this promoter with Hela nuclear extract and activator under conditions known to lead to activator-dependent transcription. This involves very low DNA concentrations in the picomolar range, which enhances the efficiency of the use of template. The mixture is then passed through a Sepharose CL-4B sizing column, which enriches preinitiation complexes (Carey et al., 1986; Laybourn and Dahmus, 1990) and removes free factors, including those that might assist in reinitiation. These enriched preinitiation complexes are the substrates for the various reactions described below.

ATP But Not Abortive Initiation Substrates Can Open the DNA

The first experiments will establish conditions associated with the accumulation of either closed or open enriched preinitiation complexes. The conditions of assembly and isolation of the preinitiation complexes described above are expected to lead to the accumulation of closed complexes. This is because ATP was omitted, and prior studies indicated that ATP was required to convert a closed complex to an open complex (Wang et al., 1992a; Jiang et al., 1993). However, this needs to be confirmed directly on the complexes isolated by the column enrichment protocol.

In addition, in one prior study, abortive initiation products of the adenovirus major late promoter could be observed without added ATP. In that experiment the only sources of nucleotide were a dinucleotide primer and a low concentrations of the next encoded nucleoside triphosphate (Goodrich and Tjian, 1994). Thus the question was raised as to whether ATP was required for the conversion of a closed complex to an open complex. That is, it was suggested that in some fractionated systems open complexes might form in the absence of ATP and in the presence of substrates allowing first bond formation. Thus we tested whether the isolated E4 preinitiation complexes were in the closed state and whether they could be opened when incubated with such a nucleotide combination.

After column isolation of these preinitiation complexes, the dinucleotide UpA and 1 µM CTP were added, which corresponds to a nucleotide combination that supports an abortive initiation reaction at this promoter (confirmed below). The DNA within these complexes was then probed with potassium permanganate. This assay uses sensitivity to potassium permanganate attack as an indicator of the locally melted DNA that is associated with open transcription complexes. If strong bands (permanganate hypersites) are observed over the transcription start site, then open complexes are indicated to be present; the assay has been validated in several prior studies of this promoter (Wang et al., 1992a, 1992b; Jiang and Gralla, 1993; Jiang et al., 1994; Jiang and Gralla, 1995), although in those cases the probing was done directly in crude transcription extracts.

Fig. 1A (lanes 1 and 2) shows that permanganate hypersites over the start site region (bar at right) are not observed when the enriched preinitiation complexes are incubated with UpA and 1 µM CTP. By contrast, when 10 µM ATP or dATP is also included, open complexes are readily detected (Fig. 1A, lanes 3 and 4). UpA and CTP are not required for the opening reaction as shown by the appearance of open complexes when dATP is the only nucleotide present (Fig. 1B, lane 6). The open complexes nearly disappear when the three missing nucleoside triphosphates are included so as to allow transcription (Fig. 1B, compare lanes 7 and 6); this is expected based on studies showing that the transcription bubble moves downstream with the elongating polymerase (Wang et al., 1992a). A subsequent addition of alpha-amanitin, which can trap reinitiating complexes prior to column isolation (Jiang and Gralla, 1993), fails to restore the open complex signal (Fig. 1B, lane 8). This is the only result that differs from the properties observed in prior experiments of preinitiation complexes that were not isolated by gel filtration chromatography. The difference indicates that the chromatographic procedure has led to the removal of factors required for reinitiation.


Figure 1: Types of complexes formed under abortive initiation conditions. A, test for open complex formation. Preinitiation complexes were assembled by incubating DNA template G9E4T, activator GAL4-AH, and Hela nuclear extract and then isolated in the void volume of a Sepharose CL-4B column. 2 mM dinucleotide UpA and 1 µM CTP were added followed by probing with potassium permanganate. Lane 1, nucleotides added for 2 min; lane 2, nucleotides added for 15 min; lane 3, nucleotides and 10 µM dATP added for 2 min; lane 4, nucleotides and 10 µM dATP added for 15 min. The bar shows the open region over the transcription start site. B, effect of adding elongation substrates. Preinitiation complexes were isolated as in A. Lane 5, control without dATP; lane 6, control with 10 µM dATP for 2 min; lane 7, 125 µM all 4 NTPs for 3 min; lane 8, 125 µM NTPs for 3 min followed by 1 µg/ml alpha-amanitin for 8 min.



We make several conclusions and inferences from these experiments. First, the column-isolated preinitiation complexes formed in this protocol are in the closed complex state. The DNA start site region may be opened in the presence of a low concentration of a source of hydrolyzable ATP. Second, substrates that could direct first bond formation cannot substitute for ATP in this melting reaction. Third, the open complexes formed in the presence of ATP appear to be functional in that the transcription bubble is chased upon the addition of substrates required for elongation. In addition, the gel filtration column isolation of large preinitiation complexes appears to have removed the free factors required to form new open complexes once the isolated complexes have transcribed. We now establish conditions associated with abortive initiation from these enriched preinitiation complexes.

Open But Not Closed Complexes Direct alpha-Amanitin-sensitive Short RNA Synthesis

Enriched preinitiation complexes were incubated with UpA and 1 µM [alpha-P]CTP, and the products were separated on 25% acrylamide/urea gels designed to separate trinucleotide products from the large excess of unincorporated CTP and from radioactive contaminants (Carpousis and Gralla, 1980). Under these conditions the short product in lane 4 of Fig. 2is observed (position indicated by an arrow). The mobility of this band is in the region of the 25% gel that corresponds to very short RNA species of appropriate length. The appearance of the species on the autoradiograph demonstrates that it contains radioactivity from CTP, which is the only source of radioactivity in the experiment. The band is the only one that is not diminished by treatment with phosphatase, which changes the mobility of RNA bands with triphosphate ends (not shown); this confirms that the product does not contain CTP at its 5` terminus. If UpA is omitted, the short RNA is the only radioactive band to disappear (lane 2). This band thus has the characteristics expected of the abortive initiation product UpApC. Fig. 3shows that production of this presumptive abortive initiation product UpApC is strongly inhibited by low concentrations of alpha-amanitin (lane 3 versus lane 4). The low amount of alpha-amanitin used is known to selectively block initiation by RNA polymerase II. This is the only band that is inhibited by alpha-amanitin. These various results support the specificity of the abortive initiation reaction.


Figure 2: Abortive initiation assay. The indicated nucleotides were added to enriched preinitiation complexes, and the products were separated on a 25% denaturing gel and autoradiographed. The concentrations of nucleotides are 1 µM labeled CTP, 2 mM UpA, and 10 µM dATP. The abortive initiation product is indicated by an arrow.




Figure 3: Specificity of abortive initiation. A, alpha-amanitin sensitivity in the abortive initiation assay. All samples contained 2 mM UpA and 1 µM labeled CTP. When indicated (+), alpha-amanitin was present at 1 µg/ml and dATP was present at 10 µM. B, activator requirement. As in A except no activator was present. C, on a template with the TATA box deleted. Activator was present.



These observations apply to reactions involving open complexes, that is to reactions performed in the presence of low amounts of dATP (Fig. 2, lane 4), as established by the permanganate probing of Fig. 1. When dATP is omitted, corresponding to a reaction associated with closed complex conditions, the same band appears but in lesser amount (Fig. 2, lane 3 versus the lane 4 signal from open complexes). However, the product appearing under these closed complex conditions is still made in the presence of alpha-amanitin (Fig. 3, lane 1 versus lane 2). This is in contrast to the reaction from open complexes formed in the presence of ATP. Thus the products produced in the absence of ATP (closed complex conditions) lack the hallmark associated with RNA polymerase II preinitiation complexes in that their formation is not blocked by alpha-amanitin.

Previously, we showed that in order to detect functional open complexes at this promoter, a transcription activator must be present (Wang et al., 1992a). Fig. 3B presents the results of abortive initiation assays in which activator was absent. The result is similar to that observed when ATP is absent; although some product is made (Fig. 3B, lane 8), its formation is not reproducibly inhibited by alpha-amanitin (compare lane 9 versus lane 8 with the loss of signal in the presence of activator in lane 3 versus lane 4). Thus the absence of either ATP or activator leads to a loss of ability to produce the alpha-amanitin-sensitive abortive initiation product. In addition, inactivation of the promoter by deleting the TATA box also leads to an inability to produce an alpha-amanitin-sensitive product (Fig. 3C; no loss of signal in lane 14 versus lane 13), an observation that further applies to a promoterless DNA vector (not shown). Thus production of an alpha-amanitin-resistant product requires the promoter TATA box, an activator, and ATP. These are identical to the requirements for efficient long RNA formation.

The background activity, producing trinucleotide in the presence of alpha-amanitin, is similar to that reported previously in studies of a different abortive initiation product at the adeno major late promoter (Luse and Jacob, 1987). The above data show that this activity is suppressed when ATP, promoter, and activator cooperate to form an open complex (Fig. 3, lane 3). We have not further identified this activity that produces amanitin-resistant RNA. Nonspecific reactions of RNA polymerase II and activities of other polymerases are known to catalyze formation of trinucleotide products in an alpha-amanitin-resistant reaction (de Mercoyrol et al., 1989). We emphasize that the following experiments use the criterion of appearance of the alpha-amanitin-sensitive RNA product as an indicator of an appropriate abortive initiation reaction.

The Abortive Initiation Reaction Does Not Require DNA Supercoiling or Polymerase CTD Phosphorylation

A number of factors and processes have been suggested to be involved in the transition from preinitiation complex to elongation complex (see the introduction). This overall process includes the critical step of first bond formation. Thus the influences of these factors and processes can be evaluated in the context of the abortive initiation assay. We now test roles for DNA supercoiling and for phosphorylation of the polymerase CTD.

DNA supercoiling has been shown to play an important role in influencing transcription initiation in systems using isolated components (Goodrich and Tjian, 1994; Parvin and Sharp, 1993; Timmers, 1994). Certain components are needed for the transition from preinitiation to elongation complex on linear DNA. When the DNA is supercoiled, the transition occurs in the absence of certain of these factors. It is not known if there is a requirement for supercoiling for formation of an alpha-amanitin-sensitive abortive initiation product at the promoter studied here. Therefore we repeated the abortive initiation assay but substituted a 350-base pair polymerase chain reaction fragment (from approximately -240 to +110) for the form I plasmid used in the above experiments. Fig. 4shows that the alpha-amanitin-sensitive abortive initiation product is still produced in this protocol (lane 4 versus lane 5). Thus supercoiling is not required for this reaction (as also observed at the adeno major late promoter by Jacob et al.(1991)). We cannot determine if supercoiling influences the extent of either the reaction or its dependence on ATP; this requires two difficult quantitative assays: monitoring any loss of supercoiling in the plasmid and monitoring the amount of active template that survives the column isolation for supercoiled and linear templates.


Figure 4: Effects of supercoiling and the H8 CTD kinase inhibitor. A, abortive initiation using a fragment template. All samples contain 1 µM labeled CTP and the standard concentrations of the other indicated compounds. B, effect of 2 mM H8, which was preincubated with enriched preinitiation complexes for 5 min when present (+). All samples contain standard amounts of UpA and CTP.



During transcription initiation the C-terminal domain of RNA polymerase II becomes phosphorylated. Several studies indicate that this reaction occurs during the transition from preinitiation complex to elongation complex (Laybourn and Dahmus, 1989; Payne et al., 1989; Lu et al., 1991). There is considerable uncertainty about the role of this reaction, but it is generally proposed to assist in the transition, especially at activated promoters (reviewed by Drapkin and Reinberg(1994)). Therefore we will test whether inhibiting this activity inhibits the formation of the first bond as monitored by the abortive initiation assay.

The CTD kinase activity is associated with the TFIIK component of transcription factor TFIIH (Feaver et al., 1994; Svejstrup et al., 1995). Studies on different promoters have shown that the kinase activity is inhibited by compound H8 (Serizawa et al., 1993a). This compound has been shown to inhibit CTD phosphorylation and transcription levels in the same activated adenovirus E4 transcription system used here (Jiang and Gralla, 1994).^2 However, the data of Fig. 4(lane 6 versus lane 7) show that H8 does not strongly inhibit abortive initiation from open complexes. In addition, the product produced in the presence of H8 is still sensitive to alpha-amanitin (Fig. 4, lane 10 versus lane 11). We showed previously that H8 does not inhibit the formation of open complexes at this same promoter (Jiang and Gralla, 1994).^2 Thus the results suggest that H8 inhibition of transcription, and thus the requirement for CTD kinase activity, occurs after formation of the first bond.

The Abortive Initiation Reaction Appears To Be Reiterative and Is Suppressed When Elongation Is Allowed

We next addressed the issue of whether the abortive initiation reaction occurs by reiterative synthesis (as is suggested to occur at the adeno major late promoter by Jacob et al.(1991)). In such reactions short RNA products are continuously released, and then the same preinitiation complex synthesizes them again. This is distinguished from the preinitiation complex simply making the trinucleotide and then stalling, awaiting the missing elongation substrates. In that circumstance the product has not been released and could conceivably be chased into longer products if the missing elongation substrates are added.

Two aspects of the experiment shown in Fig. 5suggest that the reiterative model applies. In this experiment enriched open complexes are incubated with UpA and CTP. At various subsequent times the formation of trinucleotide product is assayed. The amount of product is determined by PhosphorImager counting. The data (Fig. 5, diamonds) show that product is produced continuously over a 12-min time course. In prior studies of this promoter, it was determined that when all four elongation substrates are added to preinitiation complexes, the entire initiation and elongation process is complete within 2 min (Jiang and Gralla, 1993). This of course includes formation of the first bond of the mRNA. Because the abortive initiation reaction is still proceeding well beyond 2 min, it would appear to include more than one cycle of first bond formation, corresponding to the reiterative model. Contributions to this signal from forming new open complexes from dissociated components are very unlikely because such complexes form slowly and were not detected in the experiment of Fig. 1.


Figure 5: Test of reiterative synthesis. Standard abortive initiation was initiated by the addition of nucleotides, and the amount of product was determined at the indicated subsequent times (diamonds). Samples were removed after 5 min and added to either elongation substrates (triangle) or alpha-amanitin (circle). 5 min later the amount of product was measured in both cases, as shown. The numbers on the y axis are arbitrary units from PhosphorImager analysis.



Another property expected of reiterative reactions is that the RNA made is released and thus cannot be chased into longer products. Thus if the nucleotides required for elongation are added to reactions that have accumulated abortive products then their number should not be reduced. In part of the experiment of Fig. 5, the missing elongation substrates are added after abortive initiation reactions have already proceeded for 5 min; this corresponds to a time at which approximately one-half of the products that normally accumulate during the 12-min time course have already been made. 5 min after this addition of elongation substrates, the amount of abortive product was measured (triangle in Fig. 5). The results showed that there was no reduction in the amount of abortive product. Thus the products that had formed could not be chased efficiently. In addition, the addition of elongation substrates appears to have essentially halted the abortive initiation reaction (see also below). The result is similar to the one obtained if alpha-amanitin is added at the same time in a parallel reaction (circle in Fig. 5). These characteristics are those expected to be associated with a reaction that proceeds reiteratively in the absence of elongation substrates.

Finally the experiment of Fig. 6tests whether the abortive initiation reaction occurs reiteratively primarily because elongation substrates are absent. That is, it asks if a very significant amount of abortive product can accumulate during normal productive initiation that takes place in the presence of all elongation substrates. The question arises because abortive initiation does occur during normal initiation at certain prokaryotic promoters and has been suggested to occur at certain weak RNA polymerase II promoters (Carpousis and Gralla, 1980; Jacob et al., 1994).


Figure 6: Test for suppression of abortive initiation by elongation substrates. The standard abortive initiation reaction is represented by the combination of compounds shown in lane 1. Suppression of the reaction by the addition of 50 µM elongation substrates (indicated by a bar) is shown in lanes 3, 4, 7, and 8.



Fig. 6shows the amount of abortive product obtained in parallel reactions with and without elongation substrates. When 50 µM UTP, GTP, and either ATP (lane 4) or AMPPNP and dATP (lane 3) are added to the standard abortive reaction containing UpA and CTP, there is a strong decrease in the signal (compare with a standard reaction in lane 1). The comparison shows that significantly less product is seen when all four elongation substrates are present. Comparable reductions were not seen when any of the elongation substrates were added separately (not shown). In addition no new bands are seen (see Fig. 6) that might correspond to new abortive products that could accompany normal transcription initiation. Thus at this promoter the presence of elongation substrates suppresses abortive initiation, perhaps by favoring RNA extension over release, thus disfavoring the reiterative reaction.

Inhibition of CTD kinase activity by H8 can slow the escape of the polymerase from this promoter. (^3)It is not known how this happens, but one possibility is that the polymerase stalls during first bond synthesis and is caught in an abortive initiation mode. Thus it is possible that under these conditions there will be an enhanced amount of abortive initiation even though all elongation substrates are present. However, the results shown in Fig. 6suggest that this effect is either weak or absent (lanes 7 and 8 in the presence of H8 and elongation substrates versus lane 5 without elongation substrates). Thus inhibition of CTD kinase activity does not seem to trap polymerase in abortive initiation mode.


DISCUSSION

These experiments have established an abortive initiation reaction at the activated adenovirus E4 promoter and used it to determine requirements for first bond formation. There has been considerable uncertainty about these requirements, especially with regard to the role of ATP (see the introduction). We consider four activities that have previously been proposed to influence the transition from preinitiation complex to elongation complex, which of course includes the critical step of first bond formation. These are polymerase CTD kinase activity, DNA supercoiling, ATP hydrolysis, and activator function. The results of this study suggest that two of these are required for efficient first bond formation at the adenovirus E4 promoter (ATP hydrolysis and activator), whereas the other two activities are not required. We discuss the evidence for these conclusions and attempt to place them in the context of several prior studies.

The two factors that are required to produce significant amounts of alpha-amanitin-sensitive abortive initiation product are a source of beta- hydrolyzable ATP and a transcription activator. Previous studies have shown that these two factors together are necessary to produce significant amounts of open transcription complexes (Wang et al., 1992a; Jiang et al., 1993). That is, in the absence of either, the preinitiation complexes that accumulate are primarily in the closed form. We conclude that in this system only open complexes produce significant amounts of proper abortive initiation product. The role of ATP hydrolysis in this case is to trigger open complex formation, and it is therefore required indirectly in the process of first bond formation.

This conclusion may be compared with two prior studies of abortive initiation, both at the adenovirus major late promoter. Neither prior report studied open complex formation directly, but both addressed the role of ATP. In one case ATP was reported to stimulate abortive initiation (Luse and Jacob, 1987), in agreement with the current findings at the adeno E4 promoter. In addition, they found that abortive initiation in the presence of ATP was inhibited by alpha-amanitin, as was also found here. In the other case, no ATP stimulation was detected, and the response to alpha-amanitin was not tested (Goodrich and Tjian, 1994). Of the three studies, the two that agree in these respects have in common the use of Hela extracts as a source of transcription factors and the use of activated transcription (either added GAL-AH or endogenous USF). In the other study a purified basal system was used. In such systems high concentrations of both DNA template and factors allows the requirement for activator to be bypassed. It is possible that this system has also bypassed the requirement for ATP to open the DNA. Alternatively, the abortive initiation product observed in that system might result from the alpha-amanitin-resistant process described here at the E4 promoter and previously at the adeno major late promoter. The process that produces this product is not known, but an undefined activity associated with purified RNA polymerase II has been reported to produce such products on poly(dAbulletdT) templates (de Mercoyrol et al., 1989).

The data also indicate that neither DNA supercoiling nor the activity that phosphorylates the polymerase C-terminal domain is required for first bond formation. Of these the lack of requirement for polymerase phosphorylation is of greater interest because it has been proposed to affect the transition from preinitiation complex to elongation complex (Laybourn and Dahmus, 1989; Lu et al., 1991; Payne et al., 1989; Usheva et al., 1992). Studies of activated transcription have shown that the CTD phosphorylation inhibitor H8 depresses transcription levels.^3 In the same system studied here, transcription was inhibited by H8, but open complex formation was not inhibited, suggesting that CTD phosphorylation can facilitate a step after open complex formation. The current observation is that H8 also does not inhibit formation of the first bond of the mRNA, and thus we infer that the step that is facilitated by CTD phosphorylation occurs after formation of the first bond of the mRNA. As discussed elsewhere, this may occur by giving assistance to initiated polymerases in moving out of the initial transcribed region.

The data are also relevant to abortive initiation, both as an assay for first bond formation and as a phenomenon that might occur during normal transcription initiation. The experiments show that abortive initiation is strongly suppressed when all nucleoside triphosphates required for elongation are present. This observation suggests that abortive initiation is probably a relatively infrequent event during normal productive transcription initiation at the activated E4 promoter. This is consistent with a prior report that showed that allowing extension of the abortive initiation product by a single nucleotide at the adeno major late promoter leads to a reduction in signal (Luse and Jacob, 1987). In addition, repeated attempts (as in Fig. 6) have failed to detect significant amounts of longer products when nucleotides that allow elongation are present (but our experiments use only 10 ng of DNA/sample). This suggests that such longer RNAs do not accumulate in very high amounts as products of a reiterative abortive initiation reaction at this promoter. It has been reported that mutations that weaken a promoter can lead to increases in the amounts of short RNA products, including ones longer than trinucleotide (Jacob et al., 1994). Thus there appear to be cases where abortive initiation may occur during normal productive initiation, but there is not yet an example of this at a strong promoter.

Taken together with other data, a view of the initiation pathway can be developed. Closed preinitiation complexes assemble in response to activators, and then the DNA within them is opened by ATP hydrolysis. The first bond of the mRNA can then form and then several more bonds. Further extension of the transcript is stimulated by the ATP-dependent phosphorylation of the polymerase. At some point the polymerase clears the promoter, allowing entry of a new polymerase for reinitiation. Further challenges include testing this model and determining whether there are important promoter-dependent variations within it.


FOOTNOTES

*
This research was supported by National Institutes of Health Grant GM49048 and in part by a grant from the National Science Foundation. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
These two authors contributed equally to this work.

To whom correspondence should be addressed. Tel.: 310-825-1620; Fax: 310-206-7286; gralla@ewald.mbi.ucla.edu.

(^1)
The abbreviations used are: CTD, C-terminal domain; AMPPNP, 5`-adenylyl beta,-imidodiphosphate.

(^2)
Y. Jiang and J. D. Gralla, submitted for publication.

(^3)
Y. Jiang and J. D. Gralla, unpublished observations.


REFERENCES

  1. Bunick, D., Zandomeni, R., Ackerman, S., and Weinmann, R. (1982) Cell 29, 877-886 [Medline] [Order article via Infotrieve]
  2. Cadena, D. L., and Dahmus, M. E. (1987) J. Biol. Chem. 262, 12468-12474 [Abstract/Free Full Text]
  3. Carey, M. F., Gerrard, S. P., and Cozzarelli, N. R. (1986) J. Biol. Chem. 261, 4309-4317 [Abstract/Free Full Text]
  4. Carey, M., Leatherwood, J., and Ptashne, M. (1990) Science 247, 710-712 [Medline] [Order article via Infotrieve]
  5. Carpousis, A. J., and Gralla, J. D. (1980) Biochemistry 19, 3245-3253 [Medline] [Order article via Infotrieve]
  6. Chang, C., Kostrub, C. F., and Burton, Z. F. (1993) J. Biol. Chem. 268, 20482-20489 [Abstract/Free Full Text]
  7. Conaway, R. C., and Conaway, J. W. (1988) J. Biol. Chem. 263, 2962-2968 [Abstract/Free Full Text]
  8. Corden, J. L. (1990) Trends Biochem. Sci. 15, 383-387 [CrossRef][Medline] [Order article via Infotrieve]
  9. de Mercoyrol, L., Job, C., and Job, D. (1989) Biochemical J. 258, 165-169 [Medline] [Order article via Infotrieve]
  10. Dignam, J. D., Lebovitz, R. M., and Roeder, R. G. (1983) Nucleic Acids Res. 11, 1475-1489 [Abstract]
  11. Drapkin, R., and Reinberg, D. (1994) Trends Biochem. Sci. 19, 504-508 [CrossRef][Medline] [Order article via Infotrieve]
  12. Feaver, W. J., Svejstrup, J. Q., Henry, N. L., and Kornberg, R. D. (1994) Cell 79, 1103-1109 [Medline] [Order article via Infotrieve]
  13. Goodrich, J. A., and Tjian, R. (1994) Cell 77, 145-156 [Medline] [Order article via Infotrieve]
  14. Jacob, G. A., Luse, S. W., and Luse, D. S. (1991) J. Biol. Chem. 266, 22537-22544 [Abstract/Free Full Text]
  15. Jacob, G. A., Kitzmiller, J. A., and Luse, D. S. (1994) J. Biol. Chem. 269, 3655-3663 [Abstract/Free Full Text]
  16. Jiang, Y., and Gralla, J. D. (1993) Mol. Cell. Biol. 13, 4572-4577 [Abstract]
  17. Jiang, Y., and Gralla, J. D. (1994) Nucleic Acids Res. 22, 4958-4962 [Abstract]
  18. Jiang, Y., and Gralla, J. D. (1995) J. Biol. Chem. 270, 1277-1281 [Abstract/Free Full Text]
  19. Jiang, Y., Smale, S., and Gralla, J. D. (1993) J. Biol. Chem. 268, 6535-6540 [Abstract/Free Full Text]
  20. Jiang, Y., Triezenberg, S., and Gralla, J. D. (1994) J. Biol. Chem. 269, 5505-5508 [Abstract/Free Full Text]
  21. Krumm, A., Hickey, L. B., and Groudine, M. (1995) Genes & Dev. 9, 559-572
  22. Laybourn, P. J., and Dahmus, M. E. (1989) J. Biol. Chem. 264, 6693-6698 [Abstract/Free Full Text]
  23. Laybourn, P. J., and Dahmus, M. E. (1990) J. Biol. Chem. 265, 13165-13173 [Abstract/Free Full Text]
  24. Lee, G., and Gilman, M. (1994) Mol. Cell. Biol. 14, 4579-4587 [Abstract]
  25. Lu, H., Flores, O., Weinmann, R., and Reinberg, D. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 10004-10008 [Abstract]
  26. Luse, D. S., and Jacob, G. A. (1987) J. Biol. Chem. 262, 14990-14997 [Abstract/Free Full Text]
  27. McClure, W. R., Cech, C. L., and Johnston, D. E. (1978) J. Biol. Chem. 253, 8941-8948 [Abstract]
  28. Narayan, S., Widen, S. G., Beard, W. A., and Wilson, S. H. (1994) J. Biol. Chem. 269, 12755-12763 [Abstract/Free Full Text]
  29. Parada, C. A., Yoon, J. B., and Roeder, R. G. (1995) J. Biol. Chem. 270, 2274-2283 [Abstract/Free Full Text]
  30. Parvin, J. D., Timmers, H. T., and Sharp, P. A. (1992) Cell 68, 1135-1144 [Medline] [Order article via Infotrieve]
  31. Parvin, J. D., and Sharp, P. A. (1993) Cell 73, 533-540 [Medline] [Order article via Infotrieve]
  32. Payne, J. M., Laybourn, P. J., and Dahmus, M. E. (1989) J. Biol. Chem. 264, 19621-19629 [Abstract/Free Full Text]
  33. Rasmussen, E. B., and Lis, J. T. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 7923-7927 [Abstract/Free Full Text]
  34. Sawadogo, M., and Roeder, R. G. (1984) J. Biol. Chem. 259, 5321-5326 [Abstract/Free Full Text]
  35. Schaeffer, L., Roy, R., Humbert, S., Moncollin, V., Vermeulen, W., Hoeijmakrs, J. H. J., Chambon, P., and Egly, J.-M. (1993) Science 260, 58-63 [Medline] [Order article via Infotrieve]
  36. Serizawa, H., Conaway, J., and Conaway, R. (1993a) Nature 363, 371-374 [CrossRef][Medline] [Order article via Infotrieve]
  37. Serizawa, H., Conaway, R. C., and Conaway, J. W. (1993b) J. Biol. Chem. 268, 17300-17308 [Abstract/Free Full Text]
  38. Svejstrup, J. Q., Wang, Z., Weaver, W. J., Wu, X., Bushnell, D. A., Donahue, T. F., Friedberg, E. C., and Kornberg, R. D. (1995) Cell 80, 21-28 [Medline] [Order article via Infotrieve]
  39. Timmers, H. T. (1994) EMBO J. 13, 391-399 [Abstract]
  40. Usheva, A., Maldonado, E., Goldring, A., Lu, H., Houbavi, C., and Reinberg, D. (1992) Cell 69, 871-881 [Medline] [Order article via Infotrieve]
  41. Wang, W., Carey, M., and Gralla, J. D. (1992a) Science 255, 450-453 [Medline] [Order article via Infotrieve]
  42. Wang, W., Gralla, J. D., and Carey, M. (1992b) Genes & Dev. 6, 1716-1727
  43. Yankulov, K., Blau, J., Purton, T., Roberts, S., and Bentley, D. L. (1994) Cell 77, 749-759 [Medline] [Order article via Infotrieve]
  44. Young, R. A. (1991) Annu. Rev. Biochem. 60, 689-715 [CrossRef][Medline] [Order article via Infotrieve]

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