(Received for publication, May 15, 1995; and in revised form, August 31, 1995)
From the
The 190-base pair (bp) rDNA enhancer within the intergenic
spacer sequences of Saccharomyces cerevisiae rRNA cistrons
activates synthesis of the S-rRNA precursor about 20-fold in vivo (Mestel, , R., Yip, M., Holland, J. P., Wang, E.,
Kang, J., and Holland, M. J.(1989) Mol. Cell. Biol. 9,
1243-1254). We now report identification and analysis of
transcriptional activities mediated by three cis-acting sites
within a 90-bp portion of the rDNA enhancer designated the modulator
region. In vivo, these sequences mediated termination of
transcription by RNA polymerase I and potentiated the activity of the
rDNA enhancer element. Two trans-acting factors, REB1 and
REB2, bind independently to sites within the modulator region (Morrow,
B. E., Johnson, S. P., and Warner, J. R. (1989) J. Biol. Chem. 264, 9061-9068). We show that REB2 is identical to the ABF1
protein. Site-directed mutagenesis of REB1 and ABF1 binding sites
demonstrated uncoupling of RNA polymerase I-dependent termination from
transcriptional activation in vivo. We conclude that REB1 and
ABF1 are required for RNA polymerase I-dependent termination and
enhancer function, respectively. Since REB1 and ABF1 proteins also
regulate expression of class II genes and other nuclear functions, our
results suggest further similarities between RNA polymerase I and II
regulatory mechanisms. Two rDNA enhancers flanking a rDNA minigene
stimulated RNA polymerase I transcription in a
``multiplicative'' fashion. Deletion mapping analysis showed
that similar cis-acting sequences were required for enhancer
function when positioned upstream or downstream from a rDNA minigene.
Eucaryotic cells contain three nuclear RNA polymerases that transcribe three distinct classes of genes(1) . Despite clear differences, fundamental similarities unite transcription by the three polymerases, reflecting shared features of the reactions they catalyze (1, 2) . Of the 10-15 subunit polypeptides constituting each of the yeast RNA polymerases, five small subunits are common to all three enzymes and two additional subunits are common to RNA polymerases I and III(2) . The two largest subunits of each polymerase are unique, but share significant sequence similarity among the three forms of polymerase(1, 2) . The parallels in regulatory mechanisms extend to their core transcription factors. All three nuclear transcription systems require the TATA-binding protein(3, 4, 5, 6, 7, 8) .
Activation or repression of RNA polymerase II transcription requires additional cis-acting elements, referred to as enhancers or silencers, respectively(9, 10) . For RNA polymerase I, cis-acting sequences within the intergenic spacer region between tandemly repeated cistrons activate or enhance transcription from a gene promoter (reviewed in (11) and (12) ). In Xenopus laevis(11, 13) , Drosophila(14) , and rodents(15, 16, 17) , these enhancer elements are imperfect duplications of all or a portion of the gene promoter. Several lines of evidence show that these latter enhancer elements are binding sites for basal transcription factors that interact with the gene promoter(11, 12) .
In yeast, initiation of
rRNA synthesis from a S-rRNA gene promoter is activated
about 20-fold by a 190-bp
rDNA enhancer element which lies
within the spacer region immediately downstream from the 25 S rRNA
coding sequences of an upstream cistron and approximately 2.2 kilobase
pairs upstream from the gene promoter of a downstream
cistron(18, 19) . The sequences essential for yeast
rDNA enhancer activity overlap the 22-bp spacer promoter, previously
shown to be sufficient to support RNA polymerase I-dependent
transcription initiation in
vitro(19, 20, 21) . Thus, as has been
shown for enhancer elements in X. laevis, it is likely that
the yeast rDNA enhancer element requires sequences that bind basal
transcription factors. Interestingly, additional sequences upstream of
the spacer promoter potentiate the activity of the yeast rDNA enhancer
element. Although these upstream sequences by themselves do not
activate RNA polymerase I transcription, maximal rDNA enhancer activity
requires this modulator region in addition to the spacer promoter
region(19) . Finally, sequences near the 5` boundary of the
enhancer element mediate RNA polymerase I-dependent termination of
transcription(19) . Thus, the 190-bp yeast rDNA enhancer
element is a complex element that mediates both enhancement of rRNA
synthesis and transcription termination.
In this report, identification and characterization of the cis-acting sequences and trans-acting factors that modulate rDNA enhancer activity, as well as RNA polymerase I-dependent transcription termination, are presented.
Figure 1:
A, organization of the rDNA tandem
array in S. cerevisiae and the rDNA sequences used for
construction of rDNA minigenes. The major features indicated include:
18, 5.8, 25, and 5 S rRNA coding sequences, the S-rRNA
precursor, the rDNA enhancer (which includes a terminator and spacer
promoter (S.P.)), the
S-gene promoter, and the
S-labeled 3` processing site (scissors). B, organization of rDNA minigenes in plasmids prib1,
prib2, and prib3. Solid arrows denote
primary transcripts. The
S-fusion transcript
(prib1 and prib3) is initiated at the
S-gene promoter and extends to the
S-labeled
3` processing site. The 480-base fusion transcript (prib2) is
initiated at the
S-gene promoter and extends to a site
near the test enhancer element. The test enhancer refers to the
enhancer element, which will contain the deletion and/or base
substitution mutations indicated in the text. C, restriction
map of the minimum rDNA enhancer, -161 to +29 relative to
the HindIII site at position +1. The relative position of
the 3` end of the 550-base fusion transcript within the enhancer
element is indicated. DNA sequence in microprint is from Mestel et
al.(19) . D, structure of the modulator region
of the rDNA enhancer. DNA sequences corresponding to Sites 1, 2, and 3
are underlined. Binding site consensuses for REB1 and ABF1
within the enhancer element are indicated below the binding sites for
REB1 and ABF1, respectively. The ABF1 consensus presented was computed
at 75% certainty as detailed in text. Lowercase letters signify mismatches between the binding site consensus and the rDNA
modulator binding site. Dimensions of DNA probes derived from the
modulator region used for the analyses described in the text are
indicated, as are the positions of base substitution mutations within
Site 1, Site 2, and Site 3, respectively. Standard IUB nucleotide
symbols used. (K = G or T; M = A or C; R = A or G; Y = C or T; H,
= A, C, or T; D = A, G, or
T).
Plasmid
prib2 was constructed as follows. Plasmid prib1
+29/+131 (19) was digested with BamHI to
remove the fragment containing the S-rRNA 3` terminal
processing site, repaired with the Klenow fragment of DNA polymerase I,
and religated with insertion of a PvuII linker (Collaborative
Research). The unique EcoRI and SalI sites flanking
the enhancer element upstream from the
S-rRNA gene
promoter were then destroyed by repair with the Klenow fragment of DNA
polymerase I and mung bean nuclease, respectively, to generate plasmid
pribPvuII. A functionally wild-type enhancer element was
derived from plasmid prib1 +29/+131, which contains
rDNA enhancer element sequences extending from an EcoRI site
at position -161 to a SalI linker site at position
+29 relative to the HindIII site (position +1) in
the enhancer element (19) by digestion with EcoRI and SalI, followed by repair with the Klenow fragment of DNA
polymerase I. The wild-type enhancer element fragment was blunt-end
ligated into the test enhancer site at the unique PvuII site
in plasmid pribPvuII. Unique EcoRI and SalI
sites flanking the test enhancer were regenerated as a consequence of
ligation in plasmids prib2 wild-type (WT) and prib2
wild-type reverse orientation (WT reverse).
Derivatives of prib2 containing deletion mutations within the test enhancer element were generated by EcoRI/SalI enhancer fragment swaps between the test enhancer in prib2 WT and prib2 WT reverse and mutant enhancer elements previously isolated in prib1 (19) . Test enhancer elements carrying base substitution mutations were prepared by PCR (polymerase chain reaction) as described below and used to replace the test enhancer in prib2.
The rDNA minigene in plasmid
prib3 was constructed by ligating an EcoRI fragment
corresponding to the S-rRNA 3` terminal processing site
into the unique EcoRI site in plasmid prib2.
To prepare S100
extracts, 25-50 g of frozen cell suspension was broken in an
Eaton press. All subsequent procedures are performed at 4 °C.
Disrupted cells were suspended in an equal volume of extract buffer
containing: 50 mM Tris-HCl, pH 7.9, 10 mM MgCl, 2 mM dithiothreitol, 25% sucrose, and
20% glycerol. The suspension was adjusted to 10% of saturation by
dropwise addition of saturated ammonium sulfate, stirred for 20 min,
and centrifuged at 48,000 rpm in a Beckman Type 70Ti rotor for 3 h.
Solid ammonium sulfate (0.4 g/ml) was added to the supernatant with
adjustment to pH 7 by dropwise addition of 1 N NaOH and the
precipitate collected by centrifugation at 48,000 rpm in a Beckman Type
70Ti rotor for 30 min. The precipitate was resuspended in 5-10 ml
of buffer containing: 50 mM Tris-HCl, pH 7.4, 6 mM MgCl
, 0.2 mM EDTA, 1 mM
dithiothreitol, and 15% glycerol. The suspension was dialyzed against
two changes (1 liter each) over 12 h of the same buffer without
MgCl
. Insoluble material was removed by centrifugation in a
Sorvall SS-34 rotor at 12,000 rpm for 10 min. The supernatant was
quick-frozen by dripping into liquid nitrogen and stored at -80
°C. No loss of DNA binding activity of any of the factors described
here was detected in extracts stored up to 6 months.
Protein concentration was determined by bichinchoninic acid assay (Pierce) using a bovine serum albumin standard. DNA binding activities in 10 mg of the S100 whole cell extract were fractionated by Mono S HR5/5 FPLC (Pharmacia) cation exchange chromatography as described previously (28) using a 50-500 mM KCl linear gradient followed by step elution with 1.0 M and 2.0 M KCl. While Mono S fractions (1 ml) stored at -80 °C showed no loss of activity, binding activities were reduced when aliquots were left on ice.
DNA probes corresponding to
the modulator region of the rDNA enhancer element (EcoRI/FokI probes) were prepared by 35 rounds of PCR
using oligonucleotide primers complementary to pBR322 sequences that
flank the rDNA enhancer element (pBR322RIcw, 23b; pBR322H3ccw, 24b) in
appropriate prib1 templates. After phenol extraction, the PCR
product was precipitated from 1.2 M ammonium acetate, 55%
isopropanol. The PCR product was limit-digested with FokI and EcoRI and then treated with calf intestinal phosphatase. To
inactivate calf intestinal phosphatase, the reaction was adjusted to 40
mM EDTA and 30 mM EGTA, heated to 85 °C for 15
min, and cooled slowly to room temperature. Restriction fragments were
resolved on 8% polyacrylamide gels and visualized by ethidium bromide
staining. EcoRI/FokI fragments corresponding to the
modulator region of the rDNA enhancer were sliced from the gel, minced,
and eluted from gel slices in a siliconized tube containing 0.5 M ammonium acetate, 10 mM EDTA at 37 °C for 4 h.
Following centrifugation, the supernatant was collected and the gel
slices were reextracted with 7.5 M ammonium acetate for 1 h at
55 °C. Pooled eluate was adjusted to 0.2 M NaCl, and three
volumes of 100% ethanol were added. The DNA was recovered by
centrifugation in an SW60 rotor (Beckman) at 40,000 rpm 1 h at 4
°C, resuspended, extracted with isoamyl alcohol:CHCl
(1:24), and reprecipitated in sodium acetate to remove ammonium ion.
The recovered DNA fragment (100-200 fmol) was 5`-labeled with T4
polynucleotide kinase in a 6-µl reaction containing 50 µCi of
[
-
P]ATP as above for oligonucleotide
probes. Following heat inactivation of polynucleotide kinase,
deoxynucleotides (25 µM final) and 3 units of the Klenow
fragment of DNA polymerase I were added to the reaction mixture, which
was incubated for 20 min at 30 °C to generate blunt end fragments.
Reactions were then adjusted to 50 mM EDTA and heated to 75
°C for 15 min to inactivate the DNA polymerase. Unincorporated
nucleotides were removed, and the specific activity of the probe was
determined as for oligonucleotide probes.
To identify protein factors that bind to these sites, gel mobility shift assays were performed with Mono S-fractionated yeast whole cell extracts and DNA probes corresponding to enhancer sequences between the EcoRI site at position -161 and the FokI site at position -93 (Fig. 1D and Fig. 2). Double-stranded oligonucleotides corresponding to Sites 1, 2, and 3, designated Ribo1, Ribo2, and Ribo3 (Fig. 1, Table 1) were synthesized and used in parallel gel mobility shift assays. Two previously described double-stranded oligonucleotide probes, HMRB and HMRE, which specifically bind the factors ABF1 and RAP1, respectively, were used to standardize Mono S chromatographic profiles ( (28) and Fig. 2).
Figure 2: Identification of activities that bind the modulator region of the rDNA enhancer. S100 whole cell extracts were prepared from S. cerevisiae strain S173-6B-pep4 and fractionated by Mono S chromatography as described under ``Experimental Procedures.'' Gel mobility shift assays were performed with the DNA probes named at the left of each profile. The HMRB, HMRE, and Ribo1 oligonucleotide probes correspond to previously identified binding sites for the DNA-binding proteins ABF1, RAP1, and REB1, respectively. The chromatographic positions of ABF1, RAP1, and REB1 binding activities are indicated below the upper four profiles. S100 indicates DNA binding reactions performed with unfractionated whole cell extract. All binding profiles were performed with fractions from the same chromatographic separation. The lower four profiles reflect gel mobility shift assays using a probe corresponding to wild-type rDNA enhancer modulator region sequences and congruent probes carrying base substitution mutations in Site 1 (site1m), Site 2 (site2m), and Site 3 (site3m). The KCl gradient profile for the Mono S chromatograms is indicated below the gel mobility shift assay profiles.
REB1 binding activity detected with the Ribo1 oligonucleotide appeared as a major activity peak in fraction 42 (Fig. 2). A similar pattern of REB1 binding was observed using an EcoRI/FokI probe corresponding to wild-type rDNA enhancer sequences extending from position -161 to -93 (wild-type modulator region). An EcoRI/FokI probe containing a triple base substitution mutation within the REB1 consensus binding site, designated site1m (Fig. 1, Table 1), failed to bind REB1 (Fig. 2). To verify that the binding activity that interacts with Site 1 is REB1, gel mobility supershift assays were performed using the EcoRI/FokI probe, Mono S fraction 42, and a polyclonal antibody directed against REB1 (Fig. 3). The gel mobility shift complex was supershifted in the presence of the REB1 antibody, but not by preimmune sera (data not shown; (33) ). These data confirm that REB1 binds to Site 1 sequences.
Figure 3:
Gel mobility supershift analysis with
antibodies directed against REB1 and ABF1. Gel mobility shift assays
contained a P-labeled DNA probe corresponding to the rDNA
enhancer modulator region (EcoRI/FokI probe) and Mono
S fractionated REB1 (fraction 42) or ABF1 (fraction 31). Gel mobility
supershift assays were performed as described under ``Experimental
Procedures'' using the indicated dilutions of a REB1 polyclonal
antibody or an ABF1 monoclonal antibody. Probe Only indicates
binding reactions containing only the
P-labeled DNA probe. No Antibody indicates binding reactions lacking REB1 or ABF1
antibody, respectively.
A second DNA binding activity was detected with the wild-type modulator region and the Ribo2 oligonucleotide probe with a major activity peak in fraction 31 (Fig. 2). Surprisingly, this binding activity co-chromatographed with ABF1 protein detected by gel mobility shift assays with the HMRB oligonucleotide probe (Fig. 2). Cleavage of the EcoRI/FokI probe with MnlI at position -120 abolished binding, consistent with the published observations for REB2 (data not shown; (31) ). Although these data suggested that the REB2 binding activity corresponds to ABF1, no strong ABF1 consensus binding site was evident at Site 2. Utilizing a degenerate ABF1 consensus binding site (RTCRYKHHDDACG at 75% certainty) developed from strong ABF1 binding sites (28) and a table of nucleotide frequencies at all positions within known ABF1 binding sites, putative ABF1 binding sites in the vicinity of Site 2 were statistically ranked. This analysis revealed two poor overlapping matches to the degenerate consensus (one on each DNA strand), which varied from the consensus at 75% certainty in one of the five ``invariant'' positions, but preserved biases at degenerate positions (Fig. 1D). A 4-base substitution mutation that abolished both putative ABF1 binding sites without introducing a significant novel ABF1 binding site was generated in the enhancer element. An EcoRI/FokI probe containing these base substitution mutations, designated site2m, failed to bind REB2 in vitro (Fig. 2). To confirm that the binding activity that interacts with Site 2 is ABF1, gel mobility supershift assays were performed using the EcoRI/FokI probe, fraction 31 after Mono S chromatography, and a monoclonal antibody directed against ABF1(23) . As illustrated in Fig. 3, the gel mobility shift complex was supershifted in the presence of the ABF1 antibody. The specificity of the ABF1 monoclonal antibody was verified by showing that REB1 polyclonal antibody and a monoclonal antibody directed against the Glu-Glu epitope tag from SV40 T antigen failed to supershift the ABF1:EcoRI/FokI complex (data not shown). These data confirm that ABF1 binds to Site 2 within the rDNA enhancer element and that REB2 is ABF1.
No specific DNA binding events were detected by gel mobility shift assay with the Ribo3 oligonucleotide (data not shown).
Figure 4:
The effects of base substitution mutations
within the modulator region of the rDNA enhancer on enhancer activity in vivo. Expression of wild-type (WT) prib1
and derivatives containing base substitution mutations in Site 1
(prib1 mut1), Site 3 (prib1 mut3), and Site 2
(prib1 mut2), was monitored by Northern blotting using a probe
complementary to pBR322 reporter sequences within the minigene
transcript. The positions of the prib1 encoded S-fusion transcript and a high molecular weight (HMW) read-through transcript are indicated. Site 1 and Site 2
correspond to REB1 and ABF1 binding sites, respectively. Lanes
contained 5 µg of total cellular RNA from the yeast host strain
S173-6B carrying the plasmid minigene indicated. The GCR1 control panel
contained identical aliquots of total cellular RNA but was hybridized
with a probe corresponding to GCR1 coding sequences and served
as a control.
Expression of the minigene, designated prib1 mut1, containing the 3-base substitution mutation at Site 1 that abolishes REB1 binding in vitro, was approximately 2-fold lower than prib1 containing a wild-type enhancer element (Fig. 4). This reduction in enhancer activity is similar to that observed for prib1 derivatives containing deletion mutations that remove all or a portion of the REB1 binding site(19) .
By comparison, transcription of minigene prib1 mut3,
containing the base substitution mutation at Site 3, was reduced
4-5-fold relative to prib1 wild-type (Fig. 4). A
similar reduction in enhancer activity was previously observed for
deletion mutations that simultaneously removed Site 1 and Site 3
sequences(19) . As observed previously for deletion mutations
that removed Site 3(19) , a high molecular weight read-through
transcript was observed with prib1 mut3 (Fig. 4). We
previously showed the high M read-through
transcript hybridizes with vector sequences upstream, but not
downstream, of the RNA polymerase I minigene transcription unit in
prib1(19) . This abundant transcript apparently
initiates at BAT1, a previously identified fortuitous RNA polymerase II
promoter present in pBR322-derived sequences(34) . Thus, the
site3m mutation disrupted fortuitous termination of RNA polymerase II
transcripts by the rDNA enhancer modulator region in prib1
mut3.
Most surprisingly, expression of a minigene, designated prib1 mut2, containing the 4-base substitution at Site 2 that disrupted ABF1 binding in vitro was reduced 7-8-fold relative to wild-type prib1 in vivo (Fig. 4). Once again, the effect of the Site 2 base substitution mutations on enhancer function was comparable to a 5` deletion mutation that removed all three sites. However, unlike such a deletion mutation, no high molecular weight read-through transcript was observed for prib1 mut2.
The
prib2 minigene containing a wild-type test enhancer in the
native orientation directs RNA polymerase I-dependent termination in vivo, reflected by the production of a 480-base fusion
transcript ((19) , Fig. 5). The size of this transcript
was determined by comparison to RNA standards using both log(molecular
weight) versus relative mobility and square root(molecular
weight) versus log(relative mobility) plots (38) . The
480-base fusion transcript did not hybridize with vector sequences
upstream or downstream of the rDNA minigene present in prib2
(data not shown). Based on electrophoretic mobility, the 3` terminus of
the 480-base fusion transcript is located near the 5` end of the test
enhancer (Fig. 1C). The steady state level of the
480-base fusion transcript was lower than the steady state level of the S-fusion transcript synthesized from plasmid
prib1, despite the presence of a second enhancer in
prib2 transcripts. As shown below for prib3 and
prib2 containing a mutation in Site 2, both enhancers in
prib2 probably function. Therefore, the 480-base fusion
transcript probably has a significantly shorter half-life than
prib1 transcripts, perhaps related to the different 3` termini
of the two transcripts.
Figure 5:
Enhancer sequences required for RNA
polymerase I-dependent termination or processing. Expression of
prib1 and prib2 was monitored by Northern blotting
utilizing a hybridization probe complementary to pBR322 reporter
sequences within the rDNA minigene. Lanes contain 5 µg of total
cellular RNA from the yeast host strain S173-6B carrying the plasmid
minigene indicated. All minigenes contained rDNA elements in their
native orientation except prib2 WT reverse in which the
downstream test enhancer element was in the reverse orientation. The
wild-type enhancer includes sequences from -161 to +29
relative to the HindIII site. The GCR1 control panels
contained identical aliquots of total cellular RNA but was hybridized
with a probe corresponding to GCR1 coding sequences and served
as a control. A, orientation dependence of termination. The
positions of the S-fusion transcript (
S
FT) synthesized from prib1, the 480-base fusion
transcript (480 FT) synthesized from prib2, and a
2.2-kilobase pair read-through transcript (2200 RT)
synthesized from prib2 WT reverse are indicated. B,
identification of cis-acting sites required for RNA polymerase
I-dependent termination in vivo. Expression of wild-type
prib2 (prib2 WT) and derivatives containing base
substitution mutations in Site 1 (prib2 mut1), Site 3
(prib2 mut3), and Site 2 (prib2 mut2), was monitored
by Northern blotting using a probe complementary to pBR322 reporter
sequences within the minigene transcript. Site 1 and Site 2 correspond
to REB1 and ABF1 binding sites, respectively. The position of the
prib2 encoded 480 base fusion transcript is indicated. RNA
standard lanes were transferred to the same filter and visualized by
methylene blue staining. Standard sizes are indicated in kilobases to
the right of the panel.
As all RNA polymerase I terminators examined in vitro function only in the native orientation(39, 40, 41) , we tested the orientation dependence of the putative yeast terminator in vivo. The terminator in the prib2 minigene functioned in an orientation-dependent manner, evident by its inability to direct 480-base fusion transcript synthesis when the test enhancer was in the reverse orientation (Fig. 5A, prib2 WT reverse). Loss of 480-base fusion transcript synthesis was accompanied by the appearance of a 2200-base read-through transcript that hybridized with vector sequences downstream of the test enhancer (Fig. 5A and data not shown).
To further define the cis-acting sequences and the trans-acting factors required for RNA polymerase I termination in vivo, enhancer fragments containing base substitution mutations at Sites 1, 2, and 3 were cloned at the downstream test enhancer position in prib2. In addition to the 480-base fusion transcript, a series of larger transcripts was present that, presumably, reflect read-throughs of the termination site (Fig. 5B). The major read-through species detected have molecular weights consistent with 3` termini in the vector sequences downstream of the test enhancer. As illustrated in Fig. 5B, Site 1 base substitution mutations that disrupted REB1 binding in vitro abolished RNA polymerase I-dependent termination in vivo. No new read-through transcripts appeared, nor did the level of read-through transcripts rise commensurate with loss of the 480-base fusion transcript, suggesting either that the resulting transcripts are unstable or that only a small portion of the total transcripts share the 480-base end point (see ``Discussion''). Base substitution mutations at Site 3 and Site 2 did not affect 3` end formation. Thus, RNA polymerase I-dependent termination in vivo appears to require REB1 binding to Site 1. Base substitution mutations at Site 2 caused a decrease in enhancer activity, suggesting that the downstream enhancer in prib2 activated synthesis of the 480-base fusion transcript. In contrast to the observations made in prib1, however, mutations in Site 3 did not decrease the level of prib2 expression.
Figure 6:
Deletion mapping analysis of the
downstream test enhancer in prib3. Expression of
prib3 derivatives was monitored by Northern blotting using a
hybridization probe complementary to pBR322 reporter sequences within
the rDNA minigene. Lanes contained 5 µg of total cellular RNA from
the yeast host strain S173-6B carrying the plasmid minigene indicated.
The position of the minigene encoded S-fusion transcript (
S FT) is indicated. The wild-type enhancer
includes sequences from -161 to +29 relative to the HindIII site. Coordinates of deletion mutations reflect the
last wild-type base excluding linker present at the downstream test
enhancer position. GCR1 transcripts are detected on the same panel by
hybridization with a probe corresponding to GCR1 coding
sequences as a control.
To
test whether the downstream enhancer in prib3 functions by the
same mechanism as the upstream enhancer, enhancer elements containing
deletion mutations were cloned at the downstream test enhancer site and
tested for their effects on S-fusion transcript synthesis.
A series of 5` deletion mutations extending from position -161 to
-92 caused progressive loss of enhancer activity, whereas 3`
deletion mutations extending from position +131 to positions
-35 or -71 caused complete loss of test enhancer activity (Fig. 6).
Overall, deletion mutations in the downstream test
enhancer of prib3 affected transcription in a quantitatively
similar fashion to that observed previously when the identical deletion
mutations were tested for their effects on the activity of the enhancer
element in prib1(19) . Notably, deletion of sequences
corresponding to Site 3 in prib3 (Fig. 6,
-161/-122) did not decrease transcription as was observed
in prib1. Interestingly, a 3` deletion mutation adjacent to
the spacer promoter (prib3 +3/+131) caused either
loss of enhancer activity or no effect on enhancer activity in
approximately equal numbers of the multiple transformants analyzed. The
bipolar behavior of this deletion mutation could reflect the importance
for enhancer function of sequences within the HindIII
recognition site (+1), demonstrated in previous
studies(18) . With the exception of these mutations, the
similarity in requirement for cis-acting sequences suggests
that the two enhancers in prib3 act to stimulate S-labeled gene promoter initiation by the same mechanism.
Taken together, these results suggested that the failure of
prib2 mut1 to direct synthesis of 480-base fusion transcript (Fig. 5) was due to loss of termination rather than enhancer
function.
Deletion mutations extending from the 5` end of the enhancer element cause a progressive loss of enhancer activity consistent with the removal of two or more cis-acting regulatory sites(19) . Loss of REB1 binding caused by a base substitution mutation (prib1 mut1) in Site 1 had only a modest effect (2-fold) on transcriptional stimulation by the rDNA enhancer. This result agrees with our previous observations for a deletion mutation (prib1 -161/-148) that eliminates REB1 binding(19) . Others have also reported small effects of REB1 site deletion mutations on the activity of plasmid borne rDNA minigenes (42) as well as a tagged rDNA cistron integrated in the chromosomal rDNA tandem array (43) .
Morrow et al.(31) identified REB2 as an activity that binds weakly to the modulator region at Site 2. The weak binding hindered previous attempts to biochemically characterize REB2. Lorch et al.(44) hypothesized that REB2 might be ABF1, based on limited sequence similarity between their binding sites. We now have demonstrated directly that REB2 and ABF1 behave identically with respect to binding site selection, co-chromatography, and gel mobility supershift assays using a monoclonal antibody directed against ABF1. While we cannot unequivocally exclude all other possibilities, it appears highly probable that ABF1 is identical to REB2.
Introduction of a mutation (site2m) that abolished ABF1 binding into the rDNA enhancer elements in prib1 and prib2 caused a 7-8-fold and a 4-5-fold loss of enhancer activity, respectively. For prib1, this mutation decreased enhancer activity to a level previously observed for a 5` deletion mutation extending from position -161 to -91 that removed the REB1 and ABF1 binding sites(19) . These results are in contrast with those obtained utilizing two rDNA minigenes separated by a complete yeast rDNA spacer (45) . In this latter study, a deletion mutation that removed the ABF1 (REB2) binding site did not cause a loss of expression of either rDNA minigene, whereas a deletion mutation that removed critical sequences near the 3` end of the enhancer element caused a 3-5-fold loss of expression of both rDNA minigenes(45) . While we cannot reconcile the apparent lack of a requirement for the ABF1 (REB2) site observed in these latter experiments with those reported here, we speculate that the complete rDNA spacer used in this latter study may contain sequence elements that can compensate for loss of the ABF1 (REB2) site located within the enhancer element.
A 4-base transversion mutation at a third site (site3m) shown to be important for enhancer activity (19) had no measurable effect on REB1 binding to Site 1 or ABF1 binding to Site 2 in vitro. The site3m mutation in prib1 caused a 4-5-fold reduction in enhancer activity consistent with the results obtained for a deletion mutation in prib1, which removed the REB1 binding site and Site 3(19) . Interestingly, this latter deletion mutation did not affect the activity of the downstream enhancer in prib3, nor did the site3m mutation affect expression of the prib2 minigene. Taken together these results show that the requirement for Site 3 is only observed in the context of the prib1 rDNA minigene. A high molecular weight read-through transcript, previously observed for prib1 deletion mutations that removed Site 3 (19) , was also observed for prib1 carrying the site3m base substitution mutations. This read-through transcript probably initiates from a fortuitous RNA polymerase II promoter (designated BAT1) within plasmid pBR322 vector sequences upstream from the rDNA minigene(34) . For prib1 derivatives lacking a functional Site 3, it is possible that synthesis of the read-through transcript interferes with enhancer element activity.
We showed previously that sequences near the 5`
terminus of the rDNA enhancer element direct termination or processing
of transcripts initiated from the S-rRNA promoter in
prib2(19) . Here we show that REB1 binding to Site 1
is required for this termination/processing event in vivo.
Unfortunately, one cannot distinguish transcription termination from
RNA processing in vivo since template release of nascent RNA
within cells cannot be readily accessed. Nevertheless, REB1-dependent
release of RNA polymerase I initiated nascent RNA chains has been
observed in vitro(46) . REB1-dependent 3` end
formation occurs in vitro at a site immediately upstream of
the rDNA enhancer(41) . The 3` terminus predicted from the size
of the 480-base fusion transcript synthesized from prib2 is in
close agreement with the termination site determined in
vitro(41) , suggesting that REB1 participates in
transcription termination rather than RNA processing.
S1 nuclease mapping analysis of endogenous yeast rRNA transcripts revealed a 3` terminus (designated T2) (36) located approximately 60 bp downstream from the 3` termini corresponding to the REB1-dependent termination site synthesized in vivo from the prib2 minigene. None of the read-through transcripts from prib2 or its mutant derivatives corresponded in size to that expected for termination at the T2 site. Unfortunately, van der Sande et al.(36) did not report an S1 nuclease mapping analysis that would have detected a 3` terminus corresponding to the 480-base fusion transcript synthesized in vivo from the prib2 minigene.
Base substitution mutations that abolished REB1 binding to the downstream enhancer element in prib2 (prib2 mut1) resulted in the loss of the 480-base fusion transcript, but did not cause the appearance of novel read-through transcripts or an increase in the levels of read-through transcripts observed for the wild-type rDNA minigene in prib2. Novel read-through transcripts with significantly shorter half-lives than the 480-base fusion transcript would not have been detected. Alternatively, the REB1-dependent 480-base fusion transcript might represent only a small fraction of the total transcripts synthesized from the prib2 rDNA minigene. In this case, loss of the 480-base fusion transcript caused by the site1m mutation would result in an unmeasurable redistribution of a small percentage of total transcripts over a set of preexisting read-through transcripts. This latter model is consistent with the observation that less than 20% of total transcripts terminate at the REB1-dependent site in vitro(46) and that the steady-state levels of endogenous cellular rRNA complementary to chromosomal rDNA sequences located immediately upstream and downstream from the REB1 binding site (Site 1) are similar (36) .
The REB1-dependent terminator displayed strong orientation and factor binding site dependence in vivo consistent with in vitro assays of mouse, Xenopus, and yeast RNA polymerase I terminators(39, 40, 41, 46, 47, 48) . Experiments with purified factors suggest that REB1 is sufficient for termination in vitro(46) . In light of REB1's role in RNA polymerase II transcription, however, it seems unlikely that REB1 functions primarily as an RNA polymerase I termination factor. One possibility is that REB1's RNA polymerase I specific activities result from specific interactions with RNA polymerase I itself.
Much attention has been focused on the tandem arrangement of rRNA genes and the proposal that enhancers function by delivering RNA polymerase I and/or specific transcription factors to the gene promoter(11, 12, 13, 14, 15, 16, 17, 49, 50, 51) . The rDNA minigene in prib3 provided an opportunity to compare the properties of one (prib1) versus two enhancer elements (prib3). Deletion mapping of the downstream enhancer in prib3 indicated that similar sequences are required for downstream enhancer function as observed for the upstream enhancer(19) . In addition, the two enhancers in prib3 simulate transcription ``multiplicatively,'' As the product is greater than the sum of activation by each enhancer, such a multiplicative interaction represents a subset of synergistic effects (52) . Synergy between enhancer elements further supports the model that the two enhancers act in the same pathway. Furthermore, one interpretation of multiplicative enhancer effects is that the energetic effects of the enhancers are independent, rather than acting through cooperative complex formation(53) . It is not clear how such a model could be reconciled with models involving higher order template structures that co-localize enhancer elements(43, 54) .
Our observation of multiplicative enhancer-dependent activation of transcription differs from that reported by Johnson and Warner(54) , who observed an additive interaction of two enhancer elements and position-dependent enhancer strength when rDNA minigenes are integrated at the chromosomal URA3 locus. The topological difference between the circular plasmids used here and the linear chromosomal array used by Johnson and Warner might explain these quantitative differences.
The factors that bind the modulator region of the rDNA enhancer were previously shown to be involved in regulation of transcription by RNA polymerase II. REB1 binding sites have been identified in UAS of class II genes, centromeres, and telomeres(55, 56) . ABF1 and RAP1 are structural homologs (57) and have been implicated in silencing of the silent mating type loci, telomere function, ARS function, and coordinate control of ribosomal protein gene transcription(23, 58, 59, 60, 61) . ABF1 and RAP1 appear functionally interchangeable for ARS function(61) . REB1, ABF1, and RAP1 are abundant site-specific DNA-binding proteins, and their binding sites are ubiquitous. Given this array of seemingly unrelated biological processes, it is attractive to speculate that these are not multifunctional proteins, but rather serve an architectural function that is phenomenologically elaborated in the various activities observed.
Recent evidence suggests that transcription of vertebrate U6 genes by RNA polymerase III is regulated by OCT1, a factor that is involved in activation of RNA polymerase II-dependent transcription (reviewed in (62) ). It is possible that transcriptional activators for RNA polymerase II may also activate transcription by RNA polymerase I. In this regard, Lorch et al.(44) showed that yeast rDNA enhancer sequences corresponding to the modulator region described here could stimulate transcription of a UAS-less CYC1 structural gene cassette. They noted, however, that sequences within the yeast rDNA enhancer that correspond to the spacer promoter identified and defined by this laboratory (20, 21) prevented stimulation of CYC1 gene expression by an intact rDNA enhancer element. Thus it is possible that the modulator region of the yeast rDNA enhancer functions by a polymerase class independent mechanism to enable RNA polymerase I specific factors to interact with the spacer promoter region of the enhancer, which in turn stimulates transcriptional initiation from the rDNA gene promoter.