- Email: [email protected]
A thermostable protein factor acting on in vitro DNA transcription
BIOCHEMICAL
Vol. 45, No. 6, 1971
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
A THERMOSTABLE PROTEIN FACTOR ACTING ON IN VITRO DNA TRANSCRIPTION M. Jacquet, Institut
Received
R. Cukier-Kahn,
.J. Pla and F. Gros
de Biologie Molhculaire, Facultg des Sciences 9, Quai Saint-Bernard, Paris - France
October
9,
1971
SUMMARY A heat-stable protein factor has been purified from E. coli supernatant fractions which has the property to greatly stimulate in vitro DNA transcription when RNA polymerase is limiting. The step in transcription which is influenced by this factor is the formation of preinitiation complexes. --INTRODUCTION It is well polymerase depends play
is
regulated
act
role
by a large
in the
of Davison
ty to increase
the rate
repression (9),
(which
protein
ses partial for
can be purified we shall
which
preinitiation
report the
stimulates
transcription
at enzyme excess.
two effects, complexes
both
for
of which
A single reflect
holo-
of E. coli
appears
action
abili-
of a new cellu-
conveniency,
protein
like
their
RNA polymerase
at
extracts
is a heat
at DNA excess some
which
factors, for
fraction
"H",
fa-
7) or of psi
identification
supernatant
as Factor
(5)
stimulates
Other
been characterized
on the
rh6
of a given
(6,
(8).
and
sequences.
which
operons genes
RJJA of which
2, 3, 4)
the transcription
by the purified
from
designate
greatly
inhibition
these
we shall
(1,
CRP) protein
sensitive
of transcription paper
which
for
have also
In the present f,actor
the specificity sigma
or termination
of ribosomal
of DNA templates.
element
ble
elements
from a variety
lar
of factors, Some like
the case of the CAP (or
et al
by the DNA dependent
of initiation
on the transcription
the M protein
stable
recognition
from catabolite
This
catalyzed
variety
controlling
: such is
similarly
enzyme
RNA synthesis
used as templates.
as positive
mily of genes RNA synthesis acts
that
upon the genes
a general
Others
known
while
it
cau-
to be responsithe
level
of
(10).
RESULTS 1. - Characterization In the course procedure factor succinate
adapted stimulating eluates
of "H"
factor
of the E . coli
from
Chamberlin
DNA transcription from
a washed
RNA polymerase and Berg could
protamine-DNA
1597
(11)
purification which
be detected complex.
is outlined in the 0.2
according in Table M -0.3
to a I, M K
a
Vol. 45, No. 6, 1971
BIOCHEMICAL
AND BIOPHYSICAL
Table Outline
Alumina
1.
of RNA polymerase
and factor
Escherichia grindigg
coli
(a)
at 105,000 g p J 0.5 % Protamine sulfate precipitation 4 Pellet washed with 0.1 M DMG (c) 4 Elutions with K-Succinate :0.2M
Heating,
; 10&Z ><5
Sephadex
purification
MKE 600
2.5 hours
1st
RESEARCH COMMUNICATIONS
2nd : 0.3 min
ribosomal (b)&
G 75 fractionation + Factor "H"
discarded
supernatant
M
3rd
: 0.4
discarded
M
;
LI(
(d)
+
pellet
Ammonium sulfate (e)
4th
: 0.5
M
fractionation
(f)
chromatography 4 RNA Polymerase
(g)
DEAE cellulose
4
(a)
Disruption of cells is made in a buffer containing 0.02 0.01 M B-mercaptoethanol, 0.001 M EDTA, 50 % glycerol.
(b)
1 vol 0.5 % protamine pH 6.0.
(c)
For all protamine sulfate pellet elutions a Potter-vessel K-dimethyl glutarate pH 7, K succinate pH 6.
(d)
0.2 M K succinate and 0.3 M K succinate eluates are with ammonium sulfate. The precipitate is dissolved pH 7.5 and heated 15 minutes at 100' C,
(e)
After centrifugation on G 75 Sephadex
(f)
Folymerase
(g)
Chromatography is followed by stepwise elution in Tris-HCl, buffer pH 7.5 with 0.2 M, 0.25 M, 0.3 M, 0.4 M respectively. Enzyme activity is eluted at 0.3 M Tris-HCl. Specific activity of the enzyme is usually around 1 000 units/mg. 1 unit = 1 mpM of UMP incorporated in 20 min at 37 ' C.
Further heating heated
activity
studies
sulfate
to 1 vol
of S 100 in 0.1
pH 7.5, M K succinate
is used.
is obtained
having
between
shown
that
purification
on a G 75 Sephadex
column.
is
25 and 40 % Ammonium sulfate
the
stimulating
was achieved As illustrated
1598
DMG
pooled and precipitated in 0.02 M Tris-HCl,
of heat coagulated proteins, the supernatant in 0.02 M Tris-HCl buffer, pH 7.5.
at 1OO'C subsequent extract
is added
M Tris-HCl,
capacity by absorbing on Fig.
filtered saturation.
can sustain a 15 min pre1 the heat
stable
:
Vol. 45, No. 6, 1971
Figure
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
1 - Gel filtration of partially purified H-factor 1 x 80 cm G 75 Sephadex column was used ; Buffer : dinitrophenyl-alanine.
Marker
component fraction single
resolves non excluded
band
conditions, plus
into
after
two components, from
giving
rate
(Fig.
can be assigned
two sub'fractions
fraction
II.
- Effects
of "H"
Under
conditions
stimulating
by the purified whether
using
purification various
From its weight
has not yet factor
activity
gels
will
during
gel
reflect
as a
of 1 % SDS
filtration,
10 000 daltons.
corresponding
be subsequently
towards
"H"
Whether
the
two different
subunits
to the factor
plus
already
defined,
the transcription
the enzyme preparative
concentrations
migrates
in non-denaturing
in the presence
behavior
in the
a
been established.
RNA polymerase
3, illustrates
bands
pH 7.5
residing
factor
(pH 8.5)
M Tris-HCl
on transcription
which
E. coli
purified
of around
on SDS acrylamide
techniques
Figure
This
protein
or one main polypeptide
contaminating
high
B).
activity
electrophoresis
2).
a molecular
obtained
of the same factor
(peak
gel
to two distinct
101 mM dithiothreitol
factor
the gel
polyacrylamide
the stimulating
: 0.02
a typical
of "H" factor,
of h p lac5,
(holoenzyme). procedure
reported
purified
1599
"H" exerts
in Table
(12) using
as described
were
I (11)
and by Burgess native
a
@Boih or T4 DNA
The same results
described
by Babinet experiment
factor
obtained or the
(13).
h p lac 5 DNA and in the preceding
Vol. 45, No. 6, 1971
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Figure
2 - Acrylamide gel electrophoresis of H-factor Polyacrylamide gels were prepared and electrophorezed at 8 mA per gel as -A-B described by Weber and Osborn (15) (acrylamide 5 %, SDS 0.1 %). Prior to electrophoresis the extracts (20 pg) were incubated with 10 mM dithiothreitol, 0.1 % SDS, 21 % glycerol. The front was indicated by a metallic thread introduced through the bromophenol blue spot. A : commercial bovine Ribonuclease I B : "Peak B" from G 75 Sephadex C Electrophoresis in "non denaturing buffer of "peak B" : - acrylamide 7.5 % - buffer : Tris glycin pH 8.5
Figure
3 - Stimulating
effect
of the
factor
Indicated amounts of the "G 75 Sephadex" purified factor were incubated in 0.250 ml of the following mixture (final concentrations) : 40 mM Tris-HCl, pH 8.0, 5 mM B-mercaptoethanol, 8 mM MgC12, the four triphosphonucleotides, each at 0.4 mM, 3H UTP (10 PC/PM), RNA polymerase 1 unit, and h. p lac DNA, 7.5 pg. o 2 the triphosphonucleosides. The reaction was started by the addition 3 ml of cold trichloracetic acid Each sample was incubated at 37°C for 10 minutes. (5%) was added and the precipitate was filtered on (Millipore) nitrocellulose membranes, introduced in vials containing toluene omnifluor liquid, then counted in a Packard Tricarb liquid scintillation system. 1600
Vol. 45, No. 6, 1971
section.
As can be seen,
concentration
until
experiment, plate,
no enhancement
initial
of transcription
then
clearly
has already stimulation some light
transcription value
stimulation.
how this
remaining
constant.
decreases
system
in
factor
effect
by varying increases
with
on transcrip-
the DNA concen4, the initial DNA concentration
at DNA excess.
been noticed
A similar DNA concentration response workers (Zillig, personal communication).
by other
reaching here about but definite inhibitory
this
DNA was used as tem-
As shown on Fig.
first
factor
be observed.
of the
was influenced
in the control
with
corresponding,
denatured could
features
effect
increases
is reached, rate
the general
RESEARCH COMMUNICATIONS
rate
When heat
of the transcription
to explore
enzyme concentration
rate
AND BIOPHYSICAL
plateau
fold
we have examined
tration,
the
a certain
to a four
In order tion,
BIOCHEMICAL
tenfold ; in contrast, effect at limiting
factor addition DNA concentrations,
curve Maximal
causes
$---I* ‘. \
I I
/’
\ ‘Y
I ,
\
\
\
I I
I
I
\
\
\
\ \
I I
\
I
I
Figure
4 - Effect
as described factor.
Indicated under
From these lated
either
experiment effect
of H-factor
results,
symmetrical
was analyzed
\ Y
at different
DNA concentrations
the differential
effect
DNA concentration
to the one just under
conditions
\ \
d’
amounts of @g,-, i h DNA were used with RNA polymerase (1 unit) Fig.3,
to the absolute
\
1601
of factor
"H" could
or to the DNA/enzyme
described where
in 250 ~1 of reaction and 18 ~g of partially
was realized
enzyme concentration
be corre-
ratio.
in which increases
mixture purified
the
An factor in the
BIOCHEMICAL
Vol. 45, No. 6, 1971
Figure
5 - Effect
for
observed a high
at different
RNA polymerase
a fixed depends
amount
of DNA. It
is
ratio
at a low DNA/enzyme
of factor
"HI' itself,
of transcription
In order the factor,
a series
RNA polymerase nucleotide
to specify
the step
of experiments
was incubated
substrates,
affected
factor
(at
mixture
that
the kind
a stimulation
being
obtained
these
data
ratio.
also
is present in larger ved : when the factor observed even at a high DNA/enzyme ratio. - Stage
(Fig.51
clear
on the DNA to polymerase
and an inhibition
the concentration
III.
concentrations
Indicated amounts of RNA polymerase were added to the reaction nnder Fig. 1) containing 5 pg of @SO i h DNA and : no factor 12 ug H-factor 30 pg H-factor 60 pg H-factor
(described -.-0 -a-A-
system
of H-factor
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Moreover,
influences amounts
the type
an inhibitory
of effect
of effect effect
at
show that obser-
can be
by "H" factor in RNA transcription were
37'C)
"H" being
carried
out in
in the presence present
1602
which
is
influenced
the presence of native
or not.After
by
of rifampicin
QSOih DNA and
one minute,
enough
Vol. 45, No. 6, 1971
BIOCHEMICAL
AND BIOPHYSICAL
1603
RESEARCH COMMUNICATIONS
ON PREINITIATION
3
1 1 1 1 1 1 1 1 1 1 1 1
0 30 0 30 0 30 0 30 0 30 0 30
250 ul of reaction mixture (as defined started after 5 minutes of preincubation plus 4 ug/ml rifampicin.
7.5 7.5 7.5 7.5 7.5 7.5 7.5 7.5 2.5 2.5 1.25 1.25
in 10 min
used. The reaction was nucleoside triphosphates,
482 1668 534 1848 480 1788 822 2250 1000 600 960 220
(uumoles/ml)
UMP incorporated
COMPLEX FORMATION
in the legend of Fig. 3) were at 37'C by adding the requisite
0 0 ATP ATP UTP UTP 4 NTP 4 NTP 0 0 0 0
Components present during preincubation (5 min, 37'C.J _-____----__--------------------------------------------------Polymerase H-factor Triphospho-nucleosides DNA (pg) (units) 0.1 uM for each (!a)
EFFECT OF "H-FACTOR"
Table
BIOCHEMICAL
Vol. 45, No. 6, 1971
rifampicin
was added
activity
incorporated
was added
only
factor
present
is
is
is noticeable.
step
(13),
site
to the factor of factor
preincubated strates,
with it
with
ratio additions
experiment
initiation
DNA and RNA polymerase, the simultaneous
during
the preincubation
factor
"II"
at some late
the
not
change
RNA synthesis
in RNA synthesis. is
with
a prerequi3, a marked
the factor
of nucleotide
was sub-
and triphosphonu-
was increased of these
concerns
the factor
of the initia-
of Table
The presence
the extent
primarily
6 - Effect of H-factor on the Nitrocellulose h DNA in the presence of varying amounts
Indicated amounts of 1 pg of 3H Ic DNA (10 pC/mg) in and 2 mM S-mercaptoethanol with Each sample was c-----o -). 20 ml of 10 mM Tris-HCl, pH 8.0, dried and counted.
presence
prein-
no effect
step stage
of rifampicin factor.
DNA
that
be shown when
complexes
interaction of the polymerase step, namely specific rise to rifampicin resistant complexes (10).
Figure
their
could
additions resistant
did
the propagation
even in the absence
by adding
period
on overall
simultaneous
"H" 2, when
or inhibit
in the 1 minute
are
In the experiment rate
factor
one to conclude
whether
on transcription.
at enzyme excess effect
to test
of rifampicin
settled
involved
radio-
As shown in Table stimulate
leads
and not with are
experiments
rifampicin.
the DNA/enzyme This
effect
In parallel
can either
"H" on the transcription
The number
and decreased
with
and TCA precipitable
and rifampicin
was of interest
5 min before
cleosides.
reinitiation
it
triphosphonucleosides
tion effect
upon
When factor
related
Since
together
to rifampicin,
depending
of the factor action
1 minute
prior
system.
any further
in 10 min was measured.
after
transcription cubation
to block
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
at DNA excess
of ATP or UTP effects.
Hence,
the preinitiation
promoter
sites,
giving
filter retention of radioactive of RNA polymerase.
RNA polymerase were incubated 10 minutes, at 4"C, with : 10 mM Tris-HCl, pH 8.0 250 pl of buffer containing ( -----x----) or without 8 pg of purified H-factor filtered on nitrocellulose membrane and washed with 50 mM NaCl buffer with gentle suction. Filters were 1605
Vol. 45, No. 6, 1971
BIOCHEMICAL
Results using
obtained
radioactive amounts
tration tions
this
this
kind
it
even
of RNA polymerase of enzyme is
where
Although
by the nitrocellulose
h DNA indicate
in the absence ting
(data
not
technique bind
However
retain
preliminary
by limiat a concen-
DNA by itself
(Fig.
to various
formation
(14) DNA even
DNA retention of factor
and subject
"HI' can influence
of nucleotide
retention
"H" can weakly
in the presence
practically
is
factor
factor shown).
enhanced
of analysis
in the absence
purified
does not
that
membrane
that
greatly
latter
confirms
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
6).
interpreta-
of enzyme DNA complexes
substrates.
DISCUSSION "H" factor stimulate
appears
of the initiation Factor
to share
DNA transcription process.
M was assigned
whereas
factor
1OO'C for
"H",
likely
for
the following
fraction
size
than
namely
factor
at high,
sensitivity
;
like-sigma factor
"H" appears
that
the two effects
and an inhibition entities
at
at low DNA/ does not
appear
electrophoretically
effects.
and inhibition
effects
namely
stage
can be heated
to a single,
c)
for
: both
:
activities
To account
M factor at an early
protein,
protein
and inhibitory
in DNA transcription,
heat
Furthermore
b) the stimulatory the stimulation
act
M. The possibility
corresponding
both
on their
of activity.
to two distinct
preparation
exhibits
lies
; both
pronase-sensitive,
a stimulation
reasons
(9'
a thermolabile
clearly loss
be attributed
a) a factor defined
is
apparent
of smaller could
of being
it
in common with
ratio
difference
the property
by the factor,
enzyme ratios
The major
although
15 min without
to be a protein exerted
some properties
at low enzyme/DNA
the formation
the factor
are both both
relate
of preinitiation
mode of action
thermostable. with
the same stage
complexes.
different
explanations
can be
advanced. l.kind
of negative
enzyme-DNA tion
The primary
complexes
sites.
sized
control
being
activity,
able 2.-
volvement
could
model initiation
are not
however
difficult
for
binding
in
with
terms
of some
the formation
to non specific
part
of the specific number
sites
of polymerase
being
of
initiasyntherate unsaturated,
molecules
sites. factor
"H" effect would postulate its ine.g. by favouring local DNA unwinding. the factor would stimulate transcription by
process,
saturated energy
be explained interfer
a large portion of the chains factor "H" would reduce the overall
by a greater
these
An alternative
the activation is
with
would
excess,
sites,
be explained
to interact
sites
in
in excess,
in the normal
When promoter diminishing
at unproper
it
inhibiting
is
When DNA is
"H" could
whereby
by preferentially
initiated
the stimulation
a model
of factor
When RNA polymerase
of RNA synthesis. becoming
effect
required
to reconcile
for with
1606
interaction the
inhibitory
with
these effect
sites
; such
observed
at
Vol. 45, No. 6, 1971
enzyme excess
unless
"H" mode of action In particular, this
factor
BIOCHEMICAL
some additional and of its
the nature is under
AND BIOPHYSICAL
hypothesis
physiological
of the
transcription
being
relevance product
RESEARCH COMMUNICATIONS
made. Elucidation of factor will require further work. made in the presence
of
investigation.
ACKNOWLEDGEMENTS This work was supported by grants from the Fonds de Developpement de la Recherche Scientifique et Technique, the Centre National de la Recherche Scientifique, the Commissariat a 1'Energie Atomique, the Ligue Nationale FranGaise contre le Cancer, and the Fondation pour la Recherche Medicale FranGaise. REFERENCES 2. 3. 4. 5. 6. 7.
8. 9. 10. 11. 12. 13. 14. 15.
Burgess, R.R., A.A. Travers, J.J. Dunn and E.K.F. Bautz, Nature, 221, 43 (1969) Sugiura,M., T. Okamoto and M. Takanami, Nature, 225, 598 (1970). Travers, A.A., Nature, 225, 1009 (1970). Travers, A.A., and R.R. Burgess, Nature, 222, 537 (1970). Roberts, J.W., Nature, 224, 1168 (1969). Eron, L., R. Arditti, G. Zubay, S. Connaway, J. R. Beckwith, Proc. Nat. Acad. Sci., 68, 215 (1971). Emmer, M., de Combrugghe, B., I. Pastan and R. Perlman, Proc. Nat. Acad. Sci., 66, 180 (1970). Travers, A.A., R. Kamen, M. Cashel, Cold Spring Harbor Symp. Quant. Biol., 35, 415, (1970). Davison,J., K. Brookman, L. Pilarski, H. Echols, Cold Spring Harbor Symp. Quant Biol., 35, 95 (1970). Bautz, E.K.F. and F.A. Bautz, Nature, 226, 1219 (1970). Chamberlin, M. and P. Berg, Proc. Nat. Acad. Sci., 48, 81, (1962) Babinetn C., Biochem. Biophys. Res. Comm., 2, 639 (1967). Burgess, R.R., Ann. Rev. Biochem., vol 40, 711, (1971). Jones, O.W., and P. Berg, J. Mol. Biol., 22, 199 (1966). Weber, K., and M. Osborn, J. Biol. Chem., 244, 4406 (1969).
1607
Vol. 45, No. 6, 1971
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
A THERMOSTABLE PROTEIN FACTOR ACTING ON IN VITRO DNA TRANSCRIPTION M. Jacquet, Institut
Received
R. Cukier-Kahn,
.J. Pla and F. Gros
de Biologie Molhculaire, Facultg des Sciences 9, Quai Saint-Bernard, Paris - France
October
9,
1971
SUMMARY A heat-stable protein factor has been purified from E. coli supernatant fractions which has the property to greatly stimulate in vitro DNA transcription when RNA polymerase is limiting. The step in transcription which is influenced by this factor is the formation of preinitiation complexes. --INTRODUCTION It is well polymerase depends play
is
regulated
act
role
by a large
in the
of Davison
ty to increase
the rate
repression (9),
(which
protein
ses partial for
can be purified we shall
which
preinitiation
report the
stimulates
transcription
at enzyme excess.
two effects, complexes
both
for
of which
A single reflect
holo-
of E. coli
appears
action
abili-
of a new cellu-
conveniency,
protein
like
their
RNA polymerase
at
extracts
is a heat
at DNA excess some
which
factors, for
fraction
"H",
fa-
7) or of psi
identification
supernatant
as Factor
(5)
stimulates
Other
been characterized
on the
rh6
of a given
(6,
(8).
and
sequences.
which
operons genes
RJJA of which
2, 3, 4)
the transcription
by the purified
from
designate
greatly
inhibition
these
we shall
(1,
CRP) protein
sensitive
of transcription paper
which
for
have also
In the present f,actor
the specificity sigma
or termination
of ribosomal
of DNA templates.
element
ble
elements
from a variety
lar
of factors, Some like
the case of the CAP (or
et al
by the DNA dependent
of initiation
on the transcription
the M protein
stable
recognition
from catabolite
This
catalyzed
variety
controlling
: such is
similarly
enzyme
RNA synthesis
used as templates.
as positive
mily of genes RNA synthesis acts
that
upon the genes
a general
Others
known
while
it
cau-
to be responsithe
level
of
(10).
RESULTS 1. - Characterization In the course procedure factor succinate
adapted stimulating eluates
of "H"
factor
of the E . coli
from
Chamberlin
DNA transcription from
a washed
RNA polymerase and Berg could
protamine-DNA
1597
(11)
purification which
be detected complex.
is outlined in the 0.2
according in Table M -0.3
to a I, M K
a
Vol. 45, No. 6, 1971
BIOCHEMICAL
AND BIOPHYSICAL
Table Outline
Alumina
1.
of RNA polymerase
and factor
Escherichia grindigg
coli
(a)
at 105,000 g p J 0.5 % Protamine sulfate precipitation 4 Pellet washed with 0.1 M DMG (c) 4 Elutions with K-Succinate :0.2M
Heating,
; 10&Z ><5
Sephadex
purification
MKE 600
2.5 hours
1st
RESEARCH COMMUNICATIONS
2nd : 0.3 min
ribosomal (b)&
G 75 fractionation + Factor "H"
discarded
supernatant
M
3rd
: 0.4
discarded
M
;
LI(
(d)
+
pellet
Ammonium sulfate (e)
4th
: 0.5
M
fractionation
(f)
chromatography 4 RNA Polymerase
(g)
DEAE cellulose
4
(a)
Disruption of cells is made in a buffer containing 0.02 0.01 M B-mercaptoethanol, 0.001 M EDTA, 50 % glycerol.
(b)
1 vol 0.5 % protamine pH 6.0.
(c)
For all protamine sulfate pellet elutions a Potter-vessel K-dimethyl glutarate pH 7, K succinate pH 6.
(d)
0.2 M K succinate and 0.3 M K succinate eluates are with ammonium sulfate. The precipitate is dissolved pH 7.5 and heated 15 minutes at 100' C,
(e)
After centrifugation on G 75 Sephadex
(f)
Folymerase
(g)
Chromatography is followed by stepwise elution in Tris-HCl, buffer pH 7.5 with 0.2 M, 0.25 M, 0.3 M, 0.4 M respectively. Enzyme activity is eluted at 0.3 M Tris-HCl. Specific activity of the enzyme is usually around 1 000 units/mg. 1 unit = 1 mpM of UMP incorporated in 20 min at 37 ' C.
Further heating heated
activity
studies
sulfate
to 1 vol
of S 100 in 0.1
pH 7.5, M K succinate
is used.
is obtained
having
between
shown
that
purification
on a G 75 Sephadex
column.
is
25 and 40 % Ammonium sulfate
the
stimulating
was achieved As illustrated
1598
DMG
pooled and precipitated in 0.02 M Tris-HCl,
of heat coagulated proteins, the supernatant in 0.02 M Tris-HCl buffer, pH 7.5.
at 1OO'C subsequent extract
is added
M Tris-HCl,
capacity by absorbing on Fig.
filtered saturation.
can sustain a 15 min pre1 the heat
stable
:
Vol. 45, No. 6, 1971
Figure
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
1 - Gel filtration of partially purified H-factor 1 x 80 cm G 75 Sephadex column was used ; Buffer : dinitrophenyl-alanine.
Marker
component fraction single
resolves non excluded
band
conditions, plus
into
after
two components, from
giving
rate
(Fig.
can be assigned
two sub'fractions
fraction
II.
- Effects
of "H"
Under
conditions
stimulating
by the purified whether
using
purification various
From its weight
has not yet factor
activity
gels
will
during
gel
reflect
as a
of 1 % SDS
filtration,
10 000 daltons.
corresponding
be subsequently
towards
"H"
Whether
the
two different
subunits
to the factor
plus
already
defined,
the transcription
the enzyme preparative
concentrations
migrates
in non-denaturing
in the presence
behavior
in the
a
been established.
RNA polymerase
3, illustrates
bands
pH 7.5
residing
factor
(pH 8.5)
M Tris-HCl
on transcription
which
E. coli
purified
of around
on SDS acrylamide
techniques
Figure
This
protein
or one main polypeptide
contaminating
high
B).
activity
electrophoresis
2).
a molecular
obtained
of the same factor
(peak
gel
to two distinct
101 mM dithiothreitol
factor
the gel
polyacrylamide
the stimulating
: 0.02
a typical
of "H" factor,
of h p lac5,
(holoenzyme). procedure
reported
purified
1599
"H" exerts
in Table
(12) using
as described
were
I (11)
and by Burgess native
a
@Boih or T4 DNA
The same results
described
by Babinet experiment
factor
obtained or the
(13).
h p lac 5 DNA and in the preceding
Vol. 45, No. 6, 1971
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Figure
2 - Acrylamide gel electrophoresis of H-factor Polyacrylamide gels were prepared and electrophorezed at 8 mA per gel as -A-B described by Weber and Osborn (15) (acrylamide 5 %, SDS 0.1 %). Prior to electrophoresis the extracts (20 pg) were incubated with 10 mM dithiothreitol, 0.1 % SDS, 21 % glycerol. The front was indicated by a metallic thread introduced through the bromophenol blue spot. A : commercial bovine Ribonuclease I B : "Peak B" from G 75 Sephadex C Electrophoresis in "non denaturing buffer of "peak B" : - acrylamide 7.5 % - buffer : Tris glycin pH 8.5
Figure
3 - Stimulating
effect
of the
factor
Indicated amounts of the "G 75 Sephadex" purified factor were incubated in 0.250 ml of the following mixture (final concentrations) : 40 mM Tris-HCl, pH 8.0, 5 mM B-mercaptoethanol, 8 mM MgC12, the four triphosphonucleotides, each at 0.4 mM, 3H UTP (10 PC/PM), RNA polymerase 1 unit, and h. p lac DNA, 7.5 pg. o 2 the triphosphonucleosides. The reaction was started by the addition 3 ml of cold trichloracetic acid Each sample was incubated at 37°C for 10 minutes. (5%) was added and the precipitate was filtered on (Millipore) nitrocellulose membranes, introduced in vials containing toluene omnifluor liquid, then counted in a Packard Tricarb liquid scintillation system. 1600
Vol. 45, No. 6, 1971
section.
As can be seen,
concentration
until
experiment, plate,
no enhancement
initial
of transcription
then
clearly
has already stimulation some light
transcription value
stimulation.
how this
remaining
constant.
decreases
system
in
factor
effect
by varying increases
with
on transcrip-
the DNA concen4, the initial DNA concentration
at DNA excess.
been noticed
A similar DNA concentration response workers (Zillig, personal communication).
by other
reaching here about but definite inhibitory
this
DNA was used as tem-
As shown on Fig.
first
factor
be observed.
of the
was influenced
in the control
with
corresponding,
denatured could
features
effect
increases
is reached, rate
the general
RESEARCH COMMUNICATIONS
rate
When heat
of the transcription
to explore
enzyme concentration
rate
AND BIOPHYSICAL
plateau
fold
we have examined
tration,
the
a certain
to a four
In order tion,
BIOCHEMICAL
tenfold ; in contrast, effect at limiting
factor addition DNA concentrations,
curve Maximal
causes
$---I* ‘. \
I I
/’
\ ‘Y
I ,
\
\
\
I I
I
I
\
\
\
\ \
I I
\
I
I
Figure
4 - Effect
as described factor.
Indicated under
From these lated
either
experiment effect
of H-factor
results,
symmetrical
was analyzed
\ Y
at different
DNA concentrations
the differential
effect
DNA concentration
to the one just under
conditions
\ \
d’
amounts of @g,-, i h DNA were used with RNA polymerase (1 unit) Fig.3,
to the absolute
\
1601
of factor
"H" could
or to the DNA/enzyme
described where
in 250 ~1 of reaction and 18 ~g of partially
was realized
enzyme concentration
be corre-
ratio.
in which increases
mixture purified
the
An factor in the
BIOCHEMICAL
Vol. 45, No. 6, 1971
Figure
5 - Effect
for
observed a high
at different
RNA polymerase
a fixed depends
amount
of DNA. It
is
ratio
at a low DNA/enzyme
of factor
"HI' itself,
of transcription
In order the factor,
a series
RNA polymerase nucleotide
to specify
the step
of experiments
was incubated
substrates,
affected
factor
(at
mixture
that
the kind
a stimulation
being
obtained
these
data
ratio.
also
is present in larger ved : when the factor observed even at a high DNA/enzyme ratio. - Stage
(Fig.51
clear
on the DNA to polymerase
and an inhibition
the concentration
III.
concentrations
Indicated amounts of RNA polymerase were added to the reaction nnder Fig. 1) containing 5 pg of @SO i h DNA and : no factor 12 ug H-factor 30 pg H-factor 60 pg H-factor
(described -.-0 -a-A-
system
of H-factor
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Moreover,
influences amounts
the type
an inhibitory
of effect
of effect effect
at
show that obser-
can be
by "H" factor in RNA transcription were
37'C)
"H" being
carried
out in
in the presence present
1602
which
is
influenced
the presence of native
or not.After
by
of rifampicin
QSOih DNA and
one minute,
enough
Vol. 45, No. 6, 1971
BIOCHEMICAL
AND BIOPHYSICAL
1603
RESEARCH COMMUNICATIONS
ON PREINITIATION
3
1 1 1 1 1 1 1 1 1 1 1 1
0 30 0 30 0 30 0 30 0 30 0 30
250 ul of reaction mixture (as defined started after 5 minutes of preincubation plus 4 ug/ml rifampicin.
7.5 7.5 7.5 7.5 7.5 7.5 7.5 7.5 2.5 2.5 1.25 1.25
in 10 min
used. The reaction was nucleoside triphosphates,
482 1668 534 1848 480 1788 822 2250 1000 600 960 220
(uumoles/ml)
UMP incorporated
COMPLEX FORMATION
in the legend of Fig. 3) were at 37'C by adding the requisite
0 0 ATP ATP UTP UTP 4 NTP 4 NTP 0 0 0 0
Components present during preincubation (5 min, 37'C.J _-____----__--------------------------------------------------Polymerase H-factor Triphospho-nucleosides DNA (pg) (units) 0.1 uM for each (!a)
EFFECT OF "H-FACTOR"
Table
BIOCHEMICAL
Vol. 45, No. 6, 1971
rifampicin
was added
activity
incorporated
was added
only
factor
present
is
is
is noticeable.
step
(13),
site
to the factor of factor
preincubated strates,
with it
with
ratio additions
experiment
initiation
DNA and RNA polymerase, the simultaneous
during
the preincubation
factor
"II"
at some late
the
not
change
RNA synthesis
in RNA synthesis. is
with
a prerequi3, a marked
the factor
of nucleotide
was sub-
and triphosphonu-
was increased of these
concerns
the factor
of the initia-
of Table
The presence
the extent
primarily
6 - Effect of H-factor on the Nitrocellulose h DNA in the presence of varying amounts
Indicated amounts of 1 pg of 3H Ic DNA (10 pC/mg) in and 2 mM S-mercaptoethanol with Each sample was c-----o -). 20 ml of 10 mM Tris-HCl, pH 8.0, dried and counted.
presence
prein-
no effect
step stage
of rifampicin factor.
DNA
that
be shown when
complexes
interaction of the polymerase step, namely specific rise to rifampicin resistant complexes (10).
Figure
their
could
additions resistant
did
the propagation
even in the absence
by adding
period
on overall
simultaneous
"H" 2, when
or inhibit
in the 1 minute
are
In the experiment rate
factor
one to conclude
whether
on transcription.
at enzyme excess effect
to test
of rifampicin
settled
involved
radio-
As shown in Table stimulate
leads
and not with are
experiments
rifampicin.
the DNA/enzyme This
effect
In parallel
can either
"H" on the transcription
The number
and decreased
with
and TCA precipitable
and rifampicin
was of interest
5 min before
cleosides.
reinitiation
it
triphosphonucleosides
tion effect
upon
When factor
related
Since
together
to rifampicin,
depending
of the factor action
1 minute
prior
system.
any further
in 10 min was measured.
after
transcription cubation
to block
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
at DNA excess
of ATP or UTP effects.
Hence,
the preinitiation
promoter
sites,
giving
filter retention of radioactive of RNA polymerase.
RNA polymerase were incubated 10 minutes, at 4"C, with : 10 mM Tris-HCl, pH 8.0 250 pl of buffer containing ( -----x----) or without 8 pg of purified H-factor filtered on nitrocellulose membrane and washed with 50 mM NaCl buffer with gentle suction. Filters were 1605
Vol. 45, No. 6, 1971
BIOCHEMICAL
Results using
obtained
radioactive amounts
tration tions
this
this
kind
it
even
of RNA polymerase of enzyme is
where
Although
by the nitrocellulose
h DNA indicate
in the absence ting
(data
not
technique bind
However
retain
preliminary
by limiat a concen-
DNA by itself
(Fig.
to various
formation
(14) DNA even
DNA retention of factor
and subject
"HI' can influence
of nucleotide
retention
"H" can weakly
in the presence
practically
is
factor
factor shown).
enhanced
of analysis
in the absence
purified
does not
that
membrane
that
greatly
latter
confirms
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
6).
interpreta-
of enzyme DNA complexes
substrates.
DISCUSSION "H" factor stimulate
appears
of the initiation Factor
to share
DNA transcription process.
M was assigned
whereas
factor
1OO'C for
"H",
likely
for
the following
fraction
size
than
namely
factor
at high,
sensitivity
;
like-sigma factor
"H" appears
that
the two effects
and an inhibition entities
at
at low DNA/ does not
appear
electrophoretically
effects.
and inhibition
effects
namely
stage
can be heated
to a single,
c)
for
: both
:
activities
To account
M factor at an early
protein,
protein
and inhibitory
in DNA transcription,
heat
Furthermore
b) the stimulatory the stimulation
act
M. The possibility
corresponding
both
on their
of activity.
to two distinct
preparation
exhibits
lies
; both
pronase-sensitive,
a stimulation
reasons
(9'
a thermolabile
clearly loss
be attributed
a) a factor defined
is
apparent
of smaller could
of being
it
in common with
ratio
difference
the property
by the factor,
enzyme ratios
The major
although
15 min without
to be a protein exerted
some properties
at low enzyme/DNA
the formation
the factor
are both both
relate
of preinitiation
mode of action
thermostable. with
the same stage
complexes.
different
explanations
can be
advanced. l.kind
of negative
enzyme-DNA tion
The primary
complexes
sites.
sized
control
being
activity,
able 2.-
volvement
could
model initiation
are not
however
difficult
for
binding
in
with
terms
of some
the formation
to non specific
part
of the specific number
sites
of polymerase
being
of
initiasyntherate unsaturated,
molecules
sites. factor
"H" effect would postulate its ine.g. by favouring local DNA unwinding. the factor would stimulate transcription by
process,
saturated energy
be explained interfer
a large portion of the chains factor "H" would reduce the overall
by a greater
these
An alternative
the activation is
with
would
excess,
sites,
be explained
to interact
sites
in
in excess,
in the normal
When promoter diminishing
at unproper
it
inhibiting
is
When DNA is
"H" could
whereby
by preferentially
initiated
the stimulation
a model
of factor
When RNA polymerase
of RNA synthesis. becoming
effect
required
to reconcile
for with
1606
interaction the
inhibitory
with
these effect
sites
; such
observed
at
Vol. 45, No. 6, 1971
enzyme excess
unless
"H" mode of action In particular, this
factor
BIOCHEMICAL
some additional and of its
the nature is under
AND BIOPHYSICAL
hypothesis
physiological
of the
transcription
being
relevance product
RESEARCH COMMUNICATIONS
made. Elucidation of factor will require further work. made in the presence
of
investigation.
ACKNOWLEDGEMENTS This work was supported by grants from the Fonds de Developpement de la Recherche Scientifique et Technique, the Centre National de la Recherche Scientifique, the Commissariat a 1'Energie Atomique, the Ligue Nationale FranGaise contre le Cancer, and the Fondation pour la Recherche Medicale FranGaise. REFERENCES 2. 3. 4. 5. 6. 7.
8. 9. 10. 11. 12. 13. 14. 15.
Burgess, R.R., A.A. Travers, J.J. Dunn and E.K.F. Bautz, Nature, 221, 43 (1969) Sugiura,M., T. Okamoto and M. Takanami, Nature, 225, 598 (1970). Travers, A.A., Nature, 225, 1009 (1970). Travers, A.A., and R.R. Burgess, Nature, 222, 537 (1970). Roberts, J.W., Nature, 224, 1168 (1969). Eron, L., R. Arditti, G. Zubay, S. Connaway, J. R. Beckwith, Proc. Nat. Acad. Sci., 68, 215 (1971). Emmer, M., de Combrugghe, B., I. Pastan and R. Perlman, Proc. Nat. Acad. Sci., 66, 180 (1970). Travers, A.A., R. Kamen, M. Cashel, Cold Spring Harbor Symp. Quant. Biol., 35, 415, (1970). Davison,J., K. Brookman, L. Pilarski, H. Echols, Cold Spring Harbor Symp. Quant Biol., 35, 95 (1970). Bautz, E.K.F. and F.A. Bautz, Nature, 226, 1219 (1970). Chamberlin, M. and P. Berg, Proc. Nat. Acad. Sci., 48, 81, (1962) Babinetn C., Biochem. Biophys. Res. Comm., 2, 639 (1967). Burgess, R.R., Ann. Rev. Biochem., vol 40, 711, (1971). Jones, O.W., and P. Berg, J. Mol. Biol., 22, 199 (1966). Weber, K., and M. Osborn, J. Biol. Chem., 244, 4406 (1969).
1607