(Received for publication, September 19, 1994)
From the
In the presence of elongation factor SII, arrested RNA polymerase II ternary complexes cleave 7-17 nucleotides from the 3`-ends of their nascent RNAs. It has been shown that transcription of linear templates generates apparent run-off RNAs, which are nevertheless truncated upon incubation with SII. By using high resolution gels, we demonstrate that transcription of blunt or 3`-overhung templates with RNA polymerase II generates two populations of ternary complexes. The first class pauses 5-10 bases prior to the end of the template strand. These complexes respond to SII by cleaving approximately 9-17 nucleotide RNAs from their 3`-ends and therefore may be termed arrested. A second class of complexes, which fail to respond to SII, transcribe to within 3 bases of the end of the template strand. These complexes appear to have run off the template since they have released their nascent RNAs. Run-off transcription occurs on all types of templates, but it is the predominant reaction on DNAs with 5`-overhung ends. Thus, RNA polymerase II ternary complexes that retain 5-10 bases of contact with the template strand downstream of the catalytic site become arrested. Further reduction of downstream template contacts can lead to termination. We also show that the addition of Sarkosyl to the elongation reactions significantly changes the pattern of transcriptional arrest near the end of linear templates.
It has been appreciated for some time that a fraction of the
transcribing RNA polymerase II ternary complexes may stop transcription
after traversing certain sequences, thereby entering a state called
arrest (see, for instance, (1, 2, 3) ). The
sites that provoke arrest typically encode runs of U within the
transcript; other sequence features are usually present as
well(1, 2) . Arrested polymerases retain their RNAs in
ternary complex but cannot continue transcription. Elongation factor
SII has been shown to facilitate the passage of polymerase II through
arrest sites(4, 5, 6) . Several laboratories
have shown that in the presence of SII, arrested ternary complexes
acquire ribonuclease activity, cleaving their nascent transcripts from
the
3`-end(7, 8, 9, 10, 11, 12, 13) .
After cleavage, transcription continues from the newly created 3`-OH
group(9, 10) . Thus, the transcript cleavage activity
rescues the transcription complex from an inactive state and allows
another opportunity for passage through the arrest site. We have
demonstrated that the initial SII-facilitated cleavage by arrested
complexes usually occurs in a 7-17-nt ()increment(10) . Elongation-competent ternary
complexes that have halted transcription simply because the next NTP
needed for elongation is missing (a condition we refer to as stalling)
also cleave their nascent RNA in the presence of SII. However,
transcript cleavage in stalled complexes generates predominantly
dinucleotides (pNpNs) with trace levels of NMPs(11) . The large
difference in SII-facilitated cleavage increment between
elongation-competent stalled complexes and elongation-incompetent
arrested complexes strongly suggests that arrest is accompanied by an
internal reorganization of the ternary complex.
It has been recently reported that a significant portion of promoter-initiated RNA polymerase II ternary complexes that have transcribed to the end of linear templates do not actually run off the DNA but remain active, as judged by their ability to truncate nascent transcripts in the presence of elongation factor SII(9, 12, 14) . The initial increment of transcript cleavage was not identified in these studies, so it was not possible to determine whether the active complexes were stalled or arrested. We show here that RNA polymerase II transcription complexes that approach the end of the template can have two fates. If transcription continues to within a few bases of the end of the template strand, the ternary complex apparently dissociates. However, on some templates there is strong tendency for the transcription complexes to accumulate 5-10 nt upstream of the end of the template strand. The majority of these complexes will cleave their nascent RNAs when SII is added, and the increment of cleavage (usually 10-15 nt) clearly indicates that these complexes are arrested. Thus, the state of transcriptional arrest may be caused not only by distinctive sequences within the transcript and template but apparently also by the destabilization or loss of downstream template contacts.
To determine the nature of transcript cleavage in complexes
that have reached the end of a linear template, we used the pML20
plasmid, which contains the Ad 2 ML promoter, linearized with one of
the following restriction endonucleases: HindIII (which cuts
the template strand at position +72 relative to the
transcriptional start site, leaving a 5`-overhung end), BglI
(+220, 3`-overhung end), FspI (+213, blunt end), and PvuII (+163, blunt end). We will refer to the sets of
ternary complexes that had transcribed to the end of these templates as
pML20-HindIII, pML20-BglI, pML20-FspI, and
pML20-PvuII complexes, respectively. The strategy we employed
to generate ternary complexes on linear templates was essentially
identical to that used on circular templates(17) . Briefly,
preinitiation complexes were formed on the linear templates by
incubation in HeLa cell nuclear extracts; the complexes were purified
by gel filtration on Bio-Gel A-1.5m. Incubation in the presence of an
ApC dinucleotide primer and appropriate concentrations of GTP, UTP, and
[-
P]CTP leads to the formation of complexes
stalled after the incorporation of a U residue at position +20
(U20 complex), prior to a triple A stop. Stalled U20 complexes are very
stable and can be highly purified by transient exposure to the
detergent Sarkosyl followed by another round of gel filtration. We have
referred to this procedure as Sarkosyl rinsing(17) . The second
gel filtration step removes not only the Sarkosyl but also most DNA
binding proteins, which disassociate from the DNA in the detergent, as
well as the NTPs and Mg
. Sarkosyl rinsing also
removes the known transcript elongation factors, leaving ternary
complexes that apparently contain only RNA polymerase II itself.
Sarkosyl-rinsed complexes were chased to the end of the linear
templates by supplying Mg
and either nonlabeled NTPs
to 1 mM, which generated 5`-end-labeled transcripts, or 1
mM ATP, GTP, and UTP and 20 µM [
-
P]CTP, which generated uniformly
labeled transcripts. The latter method was used when we sought to
characterize the SII-facilitated cleavage products directly. In either
case, the RNA polymerases chased efficiently to near the end of the
template (data not shown). It is important to note that after run-off
transcription, the ternary complexes were subsequently subjected to
another round of gel filtration to remove Mg
and
unincorporated NTPs before the addition of the SII factor.
Figure 1:
Transcription to near the end of BglI-digested pML20 template and subsequent SII-facilitated
truncation. Sarkosyl-rinsed U20 complexes generated on BglI-digested pML20 template (lane1) were
run to the end of the linear template by supplying Mg and 1 mM ATP, UTP, and GTP and 20 µM [
-
P]CTP and incubating for 30 min at
37 °C. After gel filtration, the resultant run-off complexes (lane3) were incubated at 37 °C after the
addition of 7.8 mM Mg
and 10 µg/ml
recombinant SII as indicated. The RNAs were purified and then
concentrated by lyophilization. One-third of the reactions were
resolved on a 10% (acrylamide/bisacrylamide (29:1)) sequencing gel
stopped after the bromphenol blue dye marker had run 37 cm. The DNA
markers (lane2) have been previously described (17) . DNA markers of sizes 48-1169 nt are indicated at
the left as is the RNA associated with U20 complex (lane1).
pML20-BglI complexes were supplied with SII and
Mg and incubated for 5 (lane5) or
30 (lane6) min. Consistent with previous studies (9, 12, 14) , complexes that had apparently
transcribed to the end of this linear template nevertheless remained
responsive to SII. The results of the 30-min SII-facilitated reaction (lane6) demonstrated that RNA polymerase is capable
of removing hundreds of bases via the transcript truncation reaction.
The production of shortened transcripts in the presence of SII (lanes5 and 6) was accompanied by a
reduction in length of the minor population of longer RNAs, as expected
since these RNAs are associated within RNA polymerase II ternary
complexes. Also as expected, in the absence of SII, very little
transcript truncation was observed (lane4). The
broad band of RNAs associated with pML20-BglI complexes (lane3) suggested to us that transcription to the
end of the linear template actually generated a heterogenous population
of ternary complexes. Therefore, we set out to map the distribution of
the 3`-ends of the RNAs in these complexes.
Figure 2: The pML20 template and high resolution mapping of RNAs generated by run-off transcription. A, a portion of the pUC 18-based pML20 template is shown. The stippledbox represents DNA derived from the adenovirus 2 genome containing the major late promoter from -174 to +35 relative to the start site of transcription. Restriction sites within the vector downstream of the promoter are shown (H, HindIII; P, PvuII; F, FspI; B, BglI). The sites of template strand cleavage relative to the start site of transcription are indicated. The non-template strand from +35 to +77 with sites of prolonged RNA polymerase II residence time during A-limitation transcription reactions is also shown. B, lane4 contains RNAs generated by transcription to the end of the HindIII-linearized template. The length of the predominant run-off transcripts are indicated at the right. The solidarrowhead indicates the end of the template strand. Uniform RNA (lanes2 and 5) and A limitation (lane3) ladders were generated on circular pML20 template as described under ``Materials and Methods.'' The RNAs derived from RNA polymerase that had paused prior to sites of A incorporation and U35 complex are indicated at the left. The purified transcripts were resolved on an 8% (acrylamide/bisacrylamide (19:1)) sequencing gel stopped after the bromphenol blue had reached 35 cm.
Figure 6: Summary of RNA patterns generated by run-off transcription on linear DNA templates and after very early times during subsequent SII-facilitated transcript truncation. The last 25-30 base pairs of the linear templates used in this study are shown; the numbers above the sequences indicate the distance downstream of the transcription start site. Arrowheads indicate the major locations of 3`-ends generated in the initial transcription reaction. Solidarrowheads indicate SII-nonresponsive complexes; openarrowheads indicate SII-responsive complexes. The apparent location of new 3`-ends generated by transcript cleavage are indicated by the asterisks. The maximum sizes of the segments removed from the transcripts are indicated by the bars below the sequences.
We also tested a second linear template that contained a 4-nt 5`-overhang, namely the pMB5 plasmid (15) cut with EcoRI. In this case as well, transcription proceeded to within 2 nucleotides of the end of the template (data not shown). It is important to note that neither the pML20-HindIII nor the pMB5-EcoRI complexes were capable of SII-facilitated transcript truncation (data not shown). This is in contrast to complexes generated on 3`-overhung (Fig. 1) and blunt-ended templates (see below). Since polymerases appeared to be inactive after transcription to the end of the HindIII-cut template, we tested for the possibility that the ternary complexes were no longer intact. Using gel filtration with Bio-Gel A-5m, we determined that the 71- and 72-nt RNAs generated on pML20-HindIII complexes were not retained in ternary complexes since they eluted later than the DNA template (data not shown). Thus, it appears that transcription to within a few nucleotides of the end of the template strand causes destabilization of the ternary complex. If this is a general feature of ternary complexes, irrespective of the type of template end, one would predict that the SII-responsive pML20-BglI complexes must have halted transcription prior to the end of the template strand.
Figure 3:
SII-facilitated transcript cleavage by
complexes arrested near the end of linear templates. Transcription to
the end of BglI- and FspI-digested templates was
performed in the presence (lanes6-10 and 16-20) or absence (lanes1-5 and 10-15) of 0.3% Sarkosyl. After the removal of NTPs and
Sarkosyl by gel filtration, pML20-BglI (lanes1 and 6) and pML20-FspI (lanes11 and 16) complexes were supplied with 7.8 mM Mg and 1.6 µg/ml rSII as indicated. After
incubation at 37 °C for the times shown, the purified RNAs were
resolved on a single 5% (acrylamide/bisacrylamide (19:1)) sequencing
gel (29
80 cm) run until the xylene cyanol had reached 75 cm.
Transcript sizes are indicated at the left of each template
set. The solidarrowhead indicates the end of the
template strand. The RNAs in lane4 were partially
lost during purification.
Figure 5:
SII-facilitated transcript truncation by
ternary complexes arrested at the end of PvuII-digested
template. A, pML20-PvuII complexes (lane1) were supplemented with 7.8 mM Mg and 1.5 µg/ml rSII as shown. After incubation at 37 °C
for the times indicated, the RNAs were purified and resolved on a 10%
(acrylamide/bisacrylamide (19:1)) sequencing gel. Transcript sizes are
shown at the left. B, uniformly labeled
pML20-PvuII ternary complexes were supplied with 8 mM Mg
(lanes1-3), 3.2
µg/ml rSII (lane2) and 2 mM PPi (lane1) as indicated. After a 15-min incubation at
37 °C, the RNAs were purified and resolved by electrophoresis as
described in the Fig. 4legend. Marker positions are indicated
on the left (markers not shown).
Figure 4:
The cleavage products generated from
SII-facilitated transcript truncation by pML20-BglI complexes. A, one-third of the reactions described in Fig. 1were
resolved on 16 23-cm sequencing gels (28%,
acrylamide/bisacrylamide (25:3)). The bromphenol blue dye marker was
run 12.5 cm. U20 complex RNA and radiolabeled pCpC were run as
standards. The locations of notable RNAs are shown at the left. B, uniformly labeled pML20-FspI
complexes (lane2) were incubated for 5 min at 37
°C after the addition of 7.8 mM Mg
and
1.6 µg/ml rSII as indicated. The purified RNAs were fractionated as
described in panelA. Labeled RNA from U20 complex
was used as size markers (lane1), and transcript
lengths are shown at the left as are the location of the pNpN
cleavage products.
It is important to note that the polymerases that stop upstream of the template end are not simply impeded by other DNA binding proteins. Most proteins that bind DNA nonspecifically are removed by the Sarkosyl rinse before the chase step. Furthermore, when we added an additional treatment in which the Sarkosyl-rinsed early elongation complexes were treated with 100 µg/ml heparin and repurified by gel filtration, there was no change in the proportion of polymerases paused upstream of the template end or the locations at which pausing took place (data not shown). The distribution of pML20-BglI complexes shifted toward complexes halted 5-8 nt prior to the end of the template strand in chase reactions containing limiting CTP concentrations (data not shown). Thus, it is not surprising that nearly all uniformly labeled pML20-BglI complexes remained SII responsive (Fig. 1, lanes5 and 6). Run-off RNAs generated with pML20-BglI and pML20-FspI complexes were too large to separate from the template by gel filtration, which precluded a direct test for the release of RNAs from these transcription complexes. However, based on the data obtained with pML20-HindIII complexes, it seems reasonable to suppose that the transcripts that extended to within a few bases of the ends of the template strand on the BglI- and FspI-cut templates were not retained in ternary complex.
In all of the run-off experiments, we also observed a minor population of RNAs that were 1-5 nt longer than would be expected based on the length of the template strand (Fig. 2B, lane4; Fig. 3, lanes1-5 and 11-15). We are not certain of the origin of these RNAs, but in this context two points are worth noting. First, other in vitro transcription systems have also yielded run-off RNAs that were longer than the distance between the initiation site and the end of the template strand(19, 20) . Also, Johnson and Chamberlin (21) have recently observed that binary complexes of RNA polymerase II and RNA are capable of adding a small number of bases to the 3`-end of the RNA.
The rate of transcript elongation is essentially identical during transcription on linear templates in the presence or absence of 0.3% Sarkosyl ( (4) and data not shown). However, a low level of Sarkosyl affects the ability of the known elongation factors to function and inhibits initiation by RNA polymerase II(4, 6, 22, 23) , presumably by disrupting transcription factor-polymerase interactions. The results in Fig. 3, lanes6 and 16, show that the distribution of transcription complexes at the ends of BglI- and FspI-cleaved templates was altered when run-off transcription was performed in the presence of 0.3% Sarkosyl (lanes6 and 16). The detergent appeared to inhibit continued transcription by complexes that would normally transcribe to near the end of the template (compare pML20-BglI complexes in lanes1 and 6 and pML20-FspI complexes in lanes11 and 16). The inability of ternary complexes to transcribe to the end of linear templates in the presence of Sarkosyl appears to be a general phenomenon, as the vast majority of pML20-HindIII complexes halted transcription 7 nt prior to the end of the template strand under these conditions (data not shown). Sarkosyl had little effect on the accumulation or distribution of complexes that remained SII responsive (lanes 8-10 and 18-20). However, the ability of normally responsive complexes to perform the truncation reaction upon SII addition was slightly reduced after exposure to Sarkosyl.
As indicated above, SII-facilitated transcript cleavage by bona fide arrested complexes occurs in a large (7-17 nt) cleavage increment, detectable by monitoring transcript shortening at very early times after SII addition. The initial cleavage increment with pML20-BglI and pML20-FspI complexes also appeared to be large, suggesting the interesting possibility that these complexes were functionally arrested. After the 0.25-min incubation with SII, RNAs of 196-204 nt are evident with a concomitant decrease in original pML20-BglI complex transcripts (Fig. 3, lane3). Similarly, 192-197-nt RNAs accumulate in the pML20-FspI reaction (lane13). The preference for particular sites for SII-facilitated cleavage by pML20-BglI (lane8) and pML20-FspI (lane18) complexes was not altered by generating these complexes in the presence of Sarkosyl.
To determine directly
the SII-facilitated cleavage increment, we uniformly labeled
pML20-BglI and pML20-FspI complexes and resolved the
SII-facilitated cleavage products on 28% sequencing gels (Fig. 4, A and B). As expected, gel filtration
of pML20-BglI complexes removed all but a low level of the
labeling nucleotide (Fig. 4A, lane1). The 5-min SII-facilitated cleavage reaction, which
generated complexes containing primarily 192 and 193 nt RNAs (see Fig. 1, lane5; additional data not shown),
clearly liberated both large (approximately 10-17 nt) and
dinucleotide cleavage products. A time course of SII-facilitated
transcript truncation demonstrated that the maximum level of large
cleavage products was achieved within minutes, whereas the pNpNs
products continued to accumulate over time (data not shown). This is
consistent with the model that arrested complexes regain elongation
competence after the initial cleavage. The increase in the dinucleotide
products was obvious after the 30-min incubation (lane4). We also observed an increase in the level of
radiolabeled mononucleotide (presumably CMP) in reactions supplied with
SII (lanes3 and 4). However, a similar
level of this product was present in the control reaction receiving
Mg but no SII (lane2). Essentially
no other cleavage products were observed in the control reaction.
Therefore, the accumulation of this level of radiolabeled
mononucleotide was not a property of SII-facilitated cleavage.
SII-facilitated cleavage products generated by uniformly labeled
pML20-FspI complexes are displayed in Fig. 4B, lane4. The 5-min SII-facilitated cleavage reaction
liberated large (approximately 9-11 nt) fragments and pNpNs. The
sizes of the large cleavage products produced by both
pML20-BglI complexes (10-17 nt) and pML20-FspI
complexes (9-11 nt) were consistent with the initial increment of
transcript shortening observed in Fig. 3.
We observed similar properties with run-off transcription complexes generated on PvuII-digested pML20 templates. A time course of SII-facilitated cleavage using 5`-end-labeled pML20-PvuII complexes is shown in Fig. 5A. The major RNA species generated during run-off transcription were 158 and 161 nt in length (lane1); a complete run-off RNA on this template would be 163 nt long. The time course (lanes3-9) demonstrated that ternary complexes that halted transcription 5 nt prior to the end of the template strand appeared to cleave their nascent transcripts in a large increment, whereas complexes transcribing to within 2-3 nt of the end of the template did not respond to SII treatment. It is important to note that both the pattern of run-off RNAs and the initial cleavage increment were different on the two blunt-ended templates (compare Fig. 3and Fig. 5). For example, FspI-cleaved templates showed an initial cleavage increment of 9-12 nt, while PvuII-cut templates gave a 12-17-nt initial increment. These data strongly suggest that nucleic acid sequence influences the exact site(s) of both transcription cessation and subsequent SII-facilitated cleavage.
We have recently demonstrated that in the presence of pyrophosphate (PPi), complexes arrested within bona fide intrinsic arrest sites cleave their nascent RNAs at essentially the same sites used by SII-facilitated cleavage(24) . Interestingly, complexes arrested at the ends of linear templates also truncate their nascent transcripts in the presence of PPi at sites similar to those utilized during SII-facilitated truncation (Fig. 5B and additional data not shown). To illustrate, we show the products released during SII-facilitated and PPi-mediated transcript truncation by pML20-PvuII complexes. Uniformly labeled pML20-PvuII complexes (Fig. 5B) were incubated for 15 min with either SII (lane2) or PPi (lane1), and the RNAs were fractionated on a 28% sequencing gel. As expected, in the presence of SII, large RNAs were liberated; we presume that the dinucleotide products were liberated after the cleavages that generated the long RNAs, based on additional time course data not shown here. In the presence of 2 mM PPi, a similar distribution of large RNAs was observed (lane1). The large cleavage products produced in the presence of PPi should have 5`-triphosphate termini and thus should have slightly different mobilities than the 5`-monophosphate fragments generated by SII-facilitated cleavage (see (24) ; compare lanes1 and 2 in Fig. 5B). Also as expected, subsequent PPi-mediated transcript truncation via conventional pyrophosphorolysis generated NTPs (Fig. 5B, lane 1, and additional time course data not shown). These results suggest that the large PPi-mediated cleavage increment is not a unique feature of ternary complexes that become arrested within bona fide arrest sites. Rather, pyrophosphorolysis at locations far upstream of the nascent RNA 3`-end appears to be a general feature of complexes that have adopted an ``arrested'' configuration.
We have investigated in detail the fates of RNA polymerase II ternary complexes that reach the ends of various linear templates. We find that such complexes partition into two groups: those that transcribe to within 3-4 bases of the end of the template strand and those that stop transcription 5-10 bases prior to the end of the template strand. The former group does not respond to SII. These polymerases appear to have terminated transcription, as one might have expected. However, polymerases that stop 5-10 bases upstream of the end of the template strand remain responsive to SII. Remarkably, these SII-responsive complexes closely resemble complexes arrested during transcription of circular templates, based on a number of criteria. First, the initial SII-facilitated cleavage for complexes halted near the end of the template strand removes 9-17 nt fragments; subsequent cleavages by these complexes occur primarily in the dinucleotide increments characteristic of elongation-competent complexes. Both of these properties exactly parallel those of complexes that have become arrested while transcribing circular DNA templates(10) . Furthermore, arrest on circular templates may be relieved by pyrophosphorolytic transcript cleavage, which like SII-facilitated truncation generates 7-17 nt fragments from arrested complexes(24) . Pyrophosphate treatment also causes transcript cleavage by polymerases halted 5-10 bases upstream of the template end; in this case as well, cleavage occurs in a large (10-17 nt) increment (Fig. 5B and data not shown). Finally, transcription at suboptimal CTP concentrations on the BglI and PvuII templates leads to the majority of ternary complexes arresting 5-10 nt upstream of the end of the template strand, just before the incorporation of C residues into the transcript ( Fig. 1and data not shown; see also Fig. 6). Similar effects of NTP limitations on arrest within intrinsic arrest sites are well documented(2, 8, 25, 26) . Thus, SII-responsive ternary complexes paused near the ends of templates have all the characteristics previously described for complexes arrested at particular DNA sequences during transcription of circular templates.
Explanations of transcriptional arrest have focused on the influence of particular template sequences on the arrest process. Arrest generally correlates with the transcription of an A-rich segment of the template strand, such that arrested complexes contain transcripts ending in 3-5 consecutive U residues (a structure we will refer to as the U tail). Arrest sites also contain other features that influence the loss of elongation competence, since not all A-rich segments of the template strand cause arrest(2, 10) . Some arrest sites contain sequences immediately upstream of the A-rich region that encode self-complementary sections in the transcript(27, 28) . Another class of arrest sites appear to contain DNA segments at or near the point of arrest, which are capable of adopting a bent configuration(1, 2, 7, 10, 29) . The best studied of the latter class of sites contains two runs of A residues on the template strand, spaced about 10 base pairs apart(2, 7, 10) . Arrest occurs within the first A run, but the integrity of the downstream A run is required for arrest(2) . These observations led to the proposal (2) that a bent template configuration is one of the signals for transcriptional arrest. This view was further refined by Reines, (7) who suggested that transcription through intrinsic arrest sites in the bent configuration may actually impede elongation, thereby increasing the likelihood of complexes to adopt the arrested configuration. This model is consistent with the observation that extending the residence time of RNA polymerase at potential sites of arrest increases the number of complexes that become blocked in elongation(2, 8, 25, 26) .
In an initial exploration into the effects of residence time on transcriptional arrest of complexes containing U tails, we have shown that 3, 4, or 5 consecutive A residues in the template strand provide essentially no barrier to RNA polymerase II in the presence of excess NTPs. However, if the polymerase is forced to stall after the synthesis of, for example, a 5-nt U tail, about half of the ternary complexes become arrested(10) . These and other observations led us to propose that some ternary complexes in which the transcript ends in a U tail may exist in equilibrium between the active and arrested states(10) . These studies reinforced the notion that other template and/or RNA components in addition to transient pausing must be involved in ``fixing'' the arrested configuration(2, 25) .
The necessity for transcript cleavage in the relief of arrest led us to speculate that arrest reflects the loss of contact between the 3`-end of the transcript and the catalytic center of the polymerase(8) . After arrest, the active site must resume transcription from a new 3`-end, which may be as far as 17 nt upstream of the original site of polymerization. Furthermore, pyrophosphorolytic transcript cleavage by arrested complexes also occurs in a large increment (7-17 nt, Fig. 5B; see also (24) ). Thus, arrest may be viewed as a major conformational change within the RNA polymerase, one consequence of which is the upstream displacement of the catalytic center of the enzyme.
It is not immediately clear how the apparent arrest of polymerases near the ends of linear templates fits into previous observations on arrest. In particular, the 3`-ends of the RNAs within complexes that arrest near the ends of templates are not necessarily U-rich (see Fig. 6). Some recent findings suggest that arrest can occur at locations other than canonical arrest sites. Reines and Mote (14) have shown that physically blocking the path of the elongating RNA polymerase with a protein can apparently cause arrest. A new model for the ternary complex explains translocation by the alternative locking and sliding of upstream and downstream DNA binding domains(30) ; attached to these domains are the active site and domains for RNA binding. In such a model, blocking translocation might generate strain within the polymerase, which could be relieved by an upstream movement of part of the complex. This relaxation could carry the active site upstream and thereby produce arrest. Along these lines, we may explain our current results by emphasizing the importance to the RNA polymerase of appropriate contacts with the template downstream of the site of chain elongation. As the polymerase approaches within 10 bases of the end of a linear template, it should experience some loss of downstream template contacts, since footprinting studies indicate that stalled transcription complexes protect at least 15 base pairs of template downstream of the site of chain elongation from attack by DNase I(31, 32) . Thus, arrest at the end of linear templates may arise because partial or complete loss of downstream DNA contacts prevents translocation, which in turn causes a conformational change in the RNA polymerase that forces the 3`-end of the transcript away from the active site. This raises the possibility that loss or destabilization of downstream DNA contacts during transcription through intrinsic arrest sites, perhaps while they are in the bent configuration, might favor the arrested configuration. Exonuclease III footprinting studies of an arrested complex within the histone H3.3 intrinsic arrest site have demonstrated that reestablishing the elongation competency of these complexes via transcript truncation is accompanied by a slight forward extension of the downstream exonuclease III footprint boundary (33) .
The simple linkage of the loss of downstream contacts with arrest does not explain the second pathway that we observed at the end of templates, in which polymerases synthesize RNA to the end of the template strand, with apparently catastrophic consequences, instead of halting 5-10 bases upstream. However, even at the strongest arrest sites, polymerases partition between arrest and elongation competence when excess NTPs are present(1, 4, 8, 17, 25, 26) . Thus, it is not unexpected that some polymerases do not arrest 5-10 bases upstream of the end of the template strand but instead continue transcription.
We have demonstrated that the detergent Sarkosyl affects the point at which SII-nonresponsive complexes stop transcribing near the ends of linear templates (Fig. 3). The sites at which SII-responsive complexes arrest and the extent to which arrest occurs on a particular template are largely unaffected by Sarkosyl (Fig. 3). It is important to emphasize that Sarkosyl has little effect on either the rate of transcript elongation or the arrest frequency at intrinsic arrest sites (Refs. 4, 6, 17, and 25 and data not shown). Thus, in the absence of appropriate polymerase-template interactions, Sarkosyl may destabilize the ternary complex. Interestingly, under certain circumstances, RNA polymerase II-RNA binary complexes can perform a limited, non-templated polymerization reaction that is sensitive to Sarkosyl(21) .
In summary, we have shown that RNA polymerase II can fail to run off the end of linear templates by falling into a state of transcriptional arrest just before reaching the end of the template. This observation broadens the definition of the circumstances that will cause arrest. It reinforces the idea (see also Refs. 2, 10, 25) that elements other than the sequence of the nascent RNA 3`-end are important for continued transcription by the elongation complex. Achieving a detailed picture of the RNA polymerase II ternary complex and the ways in which it may fail during RNA chain elongation will be crucial to eventually understanding the control of gene expression during elongation.