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An endodeoxyribonuclease induced in E. coli by infection with λpbio transducing phages
Vol. 41, No. 1, 1970
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
AN ENDODEOXYRIBONUCLEASE INDUCED IN E. a- COLI BY INFECTION WITH WBIO Andrew Department
Received
August
TRANSDUCING PHAGES
Becker
of Medicine, University of Toronto, the Ontario Cancer Institute, Toronto, Canada.
and
21, 1970
Summary. Infection of g. coli by @& transducing phages leads to the production of a DNA endonucleolytic activity. The activity has not been detected in uninfected cells, nor in cells infected with ?, phages that do not carry the bio-containing, bacterial DNA segments. The endonuclease has been purified extensively. The purified enzyme catalyzes the production of double-strand breaks in DNA molecules. Genetic
recombination
of DNA molecules the control viral
activities
bearing
phages
mutants
in which
proceeding
endonuclease
rather
than
with
communication Materials
Signer
describes
).
infected
that
the genes
of E.
of the an
the endonucleo-
A, and with
?, particles
of the phage
chromosome.
transducing
attachment (3).
and
Unexpectedly,
a
the Xpbio's
with
recombination.
properties
h
site
infected
controlling
and certain
region
under
we compared
of biotin
markers
are
to demonstrate
at the prophage
in extracts
the purification
phage
- a set
by bacterial
carry
region,
segment
beginning
are replaced
non-essential
with
and rejoining
processes
In attempts
of this
the lw's
was encountered J. phages
so-called
recombination-subserving
A genes,
by the breakage
X, recombinational
(2)
the control
of X used were
to the right,
occurs
on the
of E. -coli
contiguous
potent
This
of this
enzyme.
and Methods Strain
Berling
of DNA under
in this
linked
by E.R.
of extracts
deletions
The deletion
of genes
(reviewed
breakage
viruses
In the case of phage
of a series
chromosome
enzymatic lytic
(1).
in bacterial
(4).
1100 is Other
Most of the hpbio
the endonuclease g. coli
phages
were
I-deficient
K strains the
gift
were
obtained
of Dr.E.R.
63
isolate from Signer.
of Durwald Drs.
and Hoffman-
C. Fuerst
Phage
Lint red 4-3
and B. Rolfe. was the
Vol.41,No.
gift
of Dr.
M. Pearson,
from
BIOCHEMICAL
M. Yarmolinsky
(5).
yields its
infection
of h for
prophage
growth
0.02
M Tris
then without
in flasks
were
ation,
then
Protein
C-labeled
cooled
polyallomer
in x DNA.
manner,
mixtures
and protein.
counting.
and 0.01
weight
conditions one unit
Activities
The assay products where
from less
of activity
than is
after
were
in the cold
during
in 0.2 M
to 2-3 x lo8 cells
to 0.02
M.
Phage were
10 min at room temperature another
20 min at 37'.
cells
harvested
pH 7.0
In the early
The
by centrifug-
I ( 8 ).
were
layered
0.5 ml water 14
the percent
the distribution
amount
64
calculated
of substrate in the
25% of the substrate the
solutions
catalyzing
for
30 min
gradients
contained
in
1.0 M
DNA was sedimented by collecting
and 5 ml Aquasol
C and 3H were
( 10 mM ),
A DNA was then
on 5 to 20% sucrose
fractionated
at
0.14
( New England
and plotted displaced
with
ml
Nucthe aid
to smaller
gradient
of unreacted
molecules
are displaced
the breakage
of
&WA
was at 30'
).
of
20 mnmoles
of purification,
Tritium-labeled
sucrose
were
the production
in 0.1 ml,
Incubation
The sucrose
gradients
for
( 50 mM ), MgC12
stages
EDTA ( 50 mM ).
with
for
assayed contained,
M BDTA ( neutral
of
scores
out
14C or 3H-thymidine,
was added
for
), Tris
endonuclease
vials
with
in L.B.
infected
Incubation
180 min at 5' and the
of a computer.
the
of a Beckman SW 56 rotor.
scintillation
sulfate
cells
The mixtures
pH 8.0,
DNA was carried
bacteria
vigorously
500 cpm/mnmole
to inhibit
of kc1 -B57s-7 by lytic
prepared
(7) and stored
from these
'as marker.
rpm for
Under
E'uerst,
at -20'.
by adding
M Tris
into
agitated
was terminated
tubes
0.05
molecular
Drs.
induction
were
labeled
of 5 and,
in ice-water,
breaks
to serve
phages
of phage
by growing
Magnesium
frozen
by thermal
Other
and Abelson
prepared
were
rapidly
( 10 mM ),
) for
from
M EDTA.
at 37'C.
X DNA ( approx.
and reaction
lear
obtained
obtained
10-l' labeling
of infection
paste
( 50 pg ) was added
samples
were
prepared
dithiothreitol
54,000
and 0.002
fractions
double-strand
NaCl,
of Thomas
the flasks
and the cell
added
were
Lambda DNA, uniformly
at a multiplicity
shaking,
media
14
cells
shaking
added
media.
pH 7.5,
Y
Radioactive
by the method
Phage-infected per ml,
x strains
were
in strain
Yloml.
in L.B.
was prepared NaCl,
Other
DNA isolation
state
of strain
lytic
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
and M. Gold.
High (6)
1,197O
marker in this
of 10% of the
DNA.
Vol.41,No.
substrate
molecules
During
mixtures
were
could
nuclease highly
under
standard
purification,
14 C and 3H-labeled
that
BIOCHEMICAL
1,197O
pooled
for
be analyzed is
purified
conditions.
when larger
DNA's
summarized fraction
were
numbers
alternated
sedimentation per
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
as substrate analysis.
centrifugation
in Table
I.
of protein
of endonuclease
Fraction 1. Alumina extract Streptomycin 3. Ammonium sulfate 4. Alumina Cy 5. DF.AE concentrate 6. Phosphocellulose
manner,
to be assayed,
pairs the number
The purification action
of reaction of fractions
of the endo-
of the enzyme,
the most
was used.
Table Summary of purification
on the
were
and consecutive
In this
was doubled.
In studies
fractions
I from AmlO-infected
Total units (x10-3) 20
Protein (mdml) 30
g. coli
1100
Specific (units/mg
activity protein) 14.8
11
2.
21 19.8
55
19
12.3
concentrate
4
0.15
3
95 200 1025
19800
All procedures were carried out at 0-4'C. Buffer A is 0.05 M h-is pH 7.5, 0.005 M 2-mercaptoethanol, 0.001 M EDTA. Buffer B is 0.005 M Kdphosphate buffer pH 6.5 containing mercaptoethanol and EDTA as in buffer A and 20% (v/v) glycerol. Freshly frozen cells (15 g) were ground with alumina to a smooth paste and the paste was extracted with buffer A. Alumina was removed by centrifugation. The extract (45 ml, OD260: 2501~~) was precipitated by the addition of 0.25 volumes of 5% streptomycin sulfate. The precipitate was discarded after centrifugation and the supernate was fractionated by precipitation with solid ammonium sulfate Virtually all the activity was precipitated between 30 -55% saturation (AS). with AS and the precipitate obtained, collected by brief centrifugation at 100,000 x g, was dissolved in 4 ml of buffer A. The AS fraction was dialyzed extensively against 200 volumes of buffer A. To 4.2 ml of this dialyzate were added 2.1 ml of alumina Cy gel (50 mg solids per ml) and, after 10 min of gentle mixing, the suspension was centrifuged and the solids discarded. The alumina Cy supernate was applied to a column of DF.AE cellulose (2 x 9 cm) equilibrated with buffer A. The column was washed with buffer A and the activity was recovered in the wash. The active fractions were pooled (15 ml total) and concentrated by The dialyzate negative pressure dialysis against buffer B to a volume of 3 ml. was applied to a column of phosphocellulose (1.5 x 10 cm) equilibrated with buffer B. The column was washed with buffer B (100 ml) and buffer B containing, The activity was first, 0.12 M KCl(50 ml) and, then, 0.2 M KC1 (40 ml). recovered in the latter fractions of the 0.2 M effluent. The active fractions were pooled (10 ml total) and concentrated to 1 ml by negative pressure dialysis against buffer A containing 50% (v/v) glycerol. The phosphocellulose concentrate 50% activity after a period of 2 months. was stored at -20°, retaining
65
Vol. 41, No. 1, 1970
Results
BIOCHEMICAL
and Discussion
Biological
source
listed
in Table
of endonuclease. II
resulted
extracts.
Extracts
from
catalyze
a significant
inactive
extracts
not
to detection
lead
5 min after
phage
here.
or cells
fractionation
mechanism
The endonuclease
it
tested
is
not
known whether
If
the endonuclease
be outside ( attachment
site
bacterial
primarily
A simple
interpretation, gene, tested,
( or
are
adjacent
did
be detected
is not
gene for
encoded
at
determined
the enzyme
in the A chromosome
II
).
cistrons
If
could
segments
the
reside
is of
proper,
present
genes
that
in either
the
on the chromosomes
x~I
deficit
mechanism
and highly
site
extremity
results. 66
infection
deleted
Secondly DNA, site
on the
endonuclease in all
the u
DNA segment.
by simultaneous
gene
adjacer
way on the presence
bacterial
of the biotin
by phage
of the
commonly
in trans
structural
deleted.
of bacterial
induction
on the appearance the
First,
of the x attachment
in a positive
site-proximal
are
stretches
the
of h genes
may depend
- that
amplified
attachment
for
of A genes
left
in common.
by specific
) had no effect
at the
properties
and to the right
induction
however
located
replaced
of an attachment
a presumptive
and XL2
the pbio's
could
endonuclease
( Table
of the prophage
on the deficit
the
chromosomes
Amlo
bacterial
);
two general
one possible
Alternatively,
to supplement
our
genes
Thus,
may depend
phage
of purification
in h bio the longest right40, and outside the region deleted in
the active
following
DNA segments
chromosome.
in the
the
and to the right
phage
incorporating
tested.
of the
missing
the activity
bacterial,
proper,
have
proximal
activity
not
e's.
The km's
host
~51 and J.% did
Cy stage
structural
is
to ~111
or in the bacterial
chromosome
the
the X segment
bacterial
the deleted
in crude
Concentration
action
of this
induces
?, genes
with
breaks.
to the alumina
in the expression
origin.
infecting
activity
infected
of double-strand
mutants, since Lb-2 pbio -11 b* specify the endonuclease are
of the
by each of the hw's
infection.
gene must
deletion
of E. coli
of the endonuclease
cells
of activity.
or bacterial
the relevant
uninfected
production
In particular,
phage
Infection
in appearance
and their
The genetic
wise
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of this for
Attemp
infection
activity
with
( Table
the endonuclease
operon, - is not
I
carried established
is a
by all by
II
BIOCHEMICAL
Vol. 41, No. 1,197O
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table Endonuclease
Infecting
II
activity
phage
of E, -- coli
Specific
activity ( units/mg
of alumina extracts protein )
1. none
CO.5
2. AC-1
<0.5
3. xb -2
CO.5
4. Xint red ---63 5. h bio +0 6. @b&11
ve27-20
'-
16 15
8. Ab2pbioll 9. mixedly infect AC1 or X2
with
Action
of the
less
5% maximum activity
is
between
6.5 and 7.5
in phosphate
buffer.
High
of DNA breakage,
endonuclease Fig.lA increasing revealed
Manganese
seen with in Tris.
the
latter
Cl-.
concentrations
is
enzyme
not an effective cation.
The reaction
thus
being
distinguished
strictly substitute;
The pH optimum proceeds
of sRNA have no effect
the activity
is
for
equally
well
on either from
that
the rate of
I (8). shows the progress proportion
velocity
sedimenting
a shoulder of intact
of reaction
of h DNA molecules
by sedimentation
a peak appears containing
each of the given strains of h phage prepared and assayed as described in
of DNA by the purified
of magnesium.
is
or extent
with were
Breakage
on the presence
reaction
infected extracts
endonuclease.
dependent than
10-14
Aelo
E_, coli 1100 cells were 20 min, cell and, after Materials and Methods.
fraction
1100
with molecules
0.82
with receive
analysis t 0.01
a relative surviving
times
time.
With
sucrose
as fast
decreases,
time,
one or more double-strand
in neutral
sedimentation
increasing
as intact constant
the
shoulder
breaks
of 0.68
molecules, + 0.01.
becomes
as
Initially,
gradients. marker
an
and
As the
more and more
VoL41,No.
1, 1970
prominent
and,
sedimentation neutral
BIOCHEMICAL
eventually, velocity
gradients
after
DNA is more effective least
two peaks,
sedimentation obtained
the profiles 0.60
when nucleolytic
- 0.70
alkaline
become most
that
of intact
denaturation
in resolving
representing
profiles
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
x DNA fragments,
events
are
of this fully
specifying
Sedimentation
through
?, DNA.
fragments.
of reacted Under
these
readily.
reaction
resemble
patterns
position
(9).
do not
in respect
FRACTIONAL
to
a
substrate
conditions,
can be detected
random
FRACTION NUMBER
in the region
and reneutralization
the product
of the products
dense
at
The
It
SIZE
Fig. 1. (A) Sedimentation profiles of X DNA reacted with 30 units of endonuclease for varying periods of time. Reaction was conducted as described in Materials and Methods and samples were taken for analysis in neutral sucrose gradients at 0 min (w), 10 min (o-----o), and 30 min (-). Sedimentation is from right to left. (B) Molecular size distribution of reaction products in neutral (u) and alkaline (o---o) gradients. Reaction was allowed to continue until approximately 30% of substrate molecules had received at least one double-strand break. Samples of the reaction mix were then analyz'ed by sedimentation in neutral and alkaline gradients. 5 to 20% sucrose alkaline gradients contained 0.1 M NaOH, 0.9 M NaCl, 0.01 M EDTA. Sodium hydroxide ( 0.1 M final concentration ) was added to samples prior to layering on alkaline gradients. Calculations for this type of analysis were according to Meselson and Yuan ( 10 ). The ordinate is arithmetic and units are arbitrary. The abcissa represents the ratio of the molecular sizes of DNA products to that of unreacted marker DNA taken as unity. Molecular sizes were calculated from sedimentation constants using Studier's equations ( 12 ). 68
BIOCHEMICAL
Vol. 41, No. 1, 1970
has been difficult intact
to generate
To compare frequencies Fig.
the number
of fragment
1B represents
fragments
" the reaction
h DNA in "pushing
sizes
in neutral
reaction,
approximately
one half
gradients
have
one or more
Fig.
1B thus
lower
suffered
levels
reveal
weight a moderate
of reaction
over
double-strand
extensive
(all
substrate
mechanism to
of enzyme action
Neither have
duplexes
breaks the role
during of this
been determined.
breaks
in DNA and for
mediate
which functions.
in the endonuclease
described
reason
the
Taken
together,
course
for
this
previously
might
with
intact
a greater
density of
cuts.
However, of the
At this
excess
when reaction type
shown in Fig.lB
are
compatible
with
precede
and are
converted
the genetics
have been
that
catalyze
implicated
@&mutants, both
of its
double-strand
(10,13)
conditionally the
genetic
appear
definition
enzyme.
is pleased to acknowledge the excellent assistance of The research was M. Stewart, and Dr. M. Roy Chowdhury. (MA-3325) from the Medical Research Council of Canada.
9, 734 (1964). Meselson, M., J. Mol. Biol., Signer, E. R., &III. Rev. Microbial., 2& 451 (1968). Manly, K. F., Signer, E. R., and Radding, C. M., Virolow, H., J. Mol. Biol., 2, Durwald, H., and Hoffman-Berling,
69
to
defective
References 1. 2. 3. 4.
a
expression
Acknowledgement The author Mrs. S. Dunbar, Mrs. supported by a grant
is
(10,ll).
studied
provide
of
in neutral
h duplexes),
the results
nor
level
double-strand
plotted.
substrate
The results
incisions
in vivo,
Studies here,
appear
of reaction
roles
of the
At this
of curves
single-strand
biological
30-40%
even more marked. pairs
nuclease
were
of intact
broken),
Endonucleases
degradative
physiological
is
in which
gradients
gradients. over
90% survival
breaks
indistinguishable.
double-strand
of single
than
sucrose
breaks , giving
in alkaline
excess
(more
of single
are virtually
fragments
of
of enzyme. the
that
single-strand
20% that
produced,
breaks.
of the molecules
than
breaks
the case where
one or more double-strand
less
concentrations
and alkaline
for
have received
high
weight
and single-strand
such an analysis
molecular
of molecular with
of double
duplexes
of smaller
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
z 177 (1969). 331 (1968).
and a
Vol. 41, No. 1, 1970
5. 6. 7. 8. 9. 10. 11. 12. 13.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Gottesman, M. E., and Yarmolinsky, M. B., Cold Spring Harb. Symp. Quant. Biol., 33, 735 (1968). Goldberg, A. R., and Howe, M., Virology, s, 200 (1969). in Nucleic Acid Research" Thomas, C. A., Jr., and Abelson, J., in 'Procedures eds.) p.553, Harper and Row, 1966. (G. L. Cantoni and D. R. Davies, Lehman, I. R., Roussos, G. G., and Pratt, E. A., J. Biol. Chem., 327, 819 (1962). Litwin, S., Shahn, E., and Kozinski, A. W., J. Virology, 5, 24 (1969). Meselson, M., and Yuan, R., Nature, 217, 1110 (1968). C., J. Mol. Biol., ll, 141 (1965). Bernardi, G., and Cordonnier, Studier, F. W., J. Mol. Biol., 11, 373 (1965). Center, M. S., Studier, F. W., and Richardson, C. C., F'roc. Natl. Acad. Sci. U. S., 65, 242 .(1970).
70
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
AN ENDODEOXYRIBONUCLEASE INDUCED IN E. a- COLI BY INFECTION WITH WBIO Andrew Department
Received
August
TRANSDUCING PHAGES
Becker
of Medicine, University of Toronto, the Ontario Cancer Institute, Toronto, Canada.
and
21, 1970
Summary. Infection of g. coli by @& transducing phages leads to the production of a DNA endonucleolytic activity. The activity has not been detected in uninfected cells, nor in cells infected with ?, phages that do not carry the bio-containing, bacterial DNA segments. The endonuclease has been purified extensively. The purified enzyme catalyzes the production of double-strand breaks in DNA molecules. Genetic
recombination
of DNA molecules the control viral
activities
bearing
phages
mutants
in which
proceeding
endonuclease
rather
than
with
communication Materials
Signer
describes
).
infected
that
the genes
of E.
of the an
the endonucleo-
A, and with
?, particles
of the phage
chromosome.
transducing
attachment (3).
and
Unexpectedly,
a
the Xpbio's
with
recombination.
properties
h
site
infected
controlling
and certain
region
under
we compared
of biotin
markers
are
to demonstrate
at the prophage
in extracts
the purification
phage
- a set
by bacterial
carry
region,
segment
beginning
are replaced
non-essential
with
and rejoining
processes
In attempts
of this
the lw's
was encountered J. phages
so-called
recombination-subserving
A genes,
by the breakage
X, recombinational
(2)
the control
of X used were
to the right,
occurs
on the
of E. -coli
contiguous
potent
This
of this
enzyme.
and Methods Strain
Berling
of DNA under
in this
linked
by E.R.
of extracts
deletions
The deletion
of genes
(reviewed
breakage
viruses
In the case of phage
of a series
chromosome
enzymatic lytic
(1).
in bacterial
(4).
1100 is Other
Most of the hpbio
the endonuclease g. coli
phages
were
I-deficient
K strains the
gift
were
obtained
of Dr.E.R.
63
isolate from Signer.
of Durwald Drs.
and Hoffman-
C. Fuerst
Phage
Lint red 4-3
and B. Rolfe. was the
Vol.41,No.
gift
of Dr.
M. Pearson,
from
BIOCHEMICAL
M. Yarmolinsky
(5).
yields its
infection
of h for
prophage
growth
0.02
M Tris
then without
in flasks
were
ation,
then
Protein
C-labeled
cooled
polyallomer
in x DNA.
manner,
mixtures
and protein.
counting.
and 0.01
weight
conditions one unit
Activities
The assay products where
from less
of activity
than is
after
were
in the cold
during
in 0.2 M
to 2-3 x lo8 cells
to 0.02
M.
Phage were
10 min at room temperature another
20 min at 37'.
cells
harvested
pH 7.0
In the early
The
by centrifug-
I ( 8 ).
were
layered
0.5 ml water 14
the percent
the distribution
amount
64
calculated
of substrate in the
25% of the substrate the
solutions
catalyzing
for
30 min
gradients
contained
in
1.0 M
DNA was sedimented by collecting
and 5 ml Aquasol
C and 3H were
( 10 mM ),
A DNA was then
on 5 to 20% sucrose
fractionated
at
0.14
( New England
and plotted displaced
with
ml
Nucthe aid
to smaller
gradient
of unreacted
molecules
are displaced
the breakage
of
&WA
was at 30'
).
of
20 mnmoles
of purification,
Tritium-labeled
sucrose
were
the production
in 0.1 ml,
Incubation
The sucrose
gradients
for
( 50 mM ), MgC12
stages
EDTA ( 50 mM ).
with
for
assayed contained,
M BDTA ( neutral
of
scores
out
14C or 3H-thymidine,
was added
for
), Tris
endonuclease
vials
with
in L.B.
infected
Incubation
180 min at 5' and the
of a computer.
the
of a Beckman SW 56 rotor.
scintillation
sulfate
cells
The mixtures
pH 8.0,
DNA was carried
bacteria
vigorously
500 cpm/mnmole
to inhibit
of kc1 -B57s-7 by lytic
prepared
(7) and stored
from these
'as marker.
rpm for
Under
E'uerst,
at -20'.
by adding
M Tris
into
agitated
was terminated
tubes
0.05
molecular
Drs.
induction
were
labeled
of 5 and,
in ice-water,
breaks
to serve
phages
of phage
by growing
Magnesium
frozen
by thermal
Other
and Abelson
prepared
were
rapidly
( 10 mM ),
) for
from
M EDTA.
at 37'C.
X DNA ( approx.
and reaction
lear
obtained
obtained
10-l' labeling
of infection
paste
( 50 pg ) was added
samples
were
prepared
dithiothreitol
54,000
and 0.002
fractions
double-strand
NaCl,
of Thomas
the flasks
and the cell
added
were
Lambda DNA, uniformly
at a multiplicity
shaking,
media
14
cells
shaking
added
media.
pH 7.5,
Y
Radioactive
by the method
Phage-infected per ml,
x strains
were
in strain
Yloml.
in L.B.
was prepared NaCl,
Other
DNA isolation
state
of strain
lytic
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
and M. Gold.
High (6)
1,197O
marker in this
of 10% of the
DNA.
Vol.41,No.
substrate
molecules
During
mixtures
were
could
nuclease highly
under
standard
purification,
14 C and 3H-labeled
that
BIOCHEMICAL
1,197O
pooled
for
be analyzed is
purified
conditions.
when larger
DNA's
summarized fraction
were
numbers
alternated
sedimentation per
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
as substrate analysis.
centrifugation
in Table
I.
of protein
of endonuclease
Fraction 1. Alumina extract Streptomycin 3. Ammonium sulfate 4. Alumina Cy 5. DF.AE concentrate 6. Phosphocellulose
manner,
to be assayed,
pairs the number
The purification action
of reaction of fractions
of the endo-
of the enzyme,
the most
was used.
Table Summary of purification
on the
were
and consecutive
In this
was doubled.
In studies
fractions
I from AmlO-infected
Total units (x10-3) 20
Protein (mdml) 30
g. coli
1100
Specific (units/mg
activity protein) 14.8
11
2.
21 19.8
55
19
12.3
concentrate
4
0.15
3
95 200 1025
19800
All procedures were carried out at 0-4'C. Buffer A is 0.05 M h-is pH 7.5, 0.005 M 2-mercaptoethanol, 0.001 M EDTA. Buffer B is 0.005 M Kdphosphate buffer pH 6.5 containing mercaptoethanol and EDTA as in buffer A and 20% (v/v) glycerol. Freshly frozen cells (15 g) were ground with alumina to a smooth paste and the paste was extracted with buffer A. Alumina was removed by centrifugation. The extract (45 ml, OD260: 2501~~) was precipitated by the addition of 0.25 volumes of 5% streptomycin sulfate. The precipitate was discarded after centrifugation and the supernate was fractionated by precipitation with solid ammonium sulfate Virtually all the activity was precipitated between 30 -55% saturation (AS). with AS and the precipitate obtained, collected by brief centrifugation at 100,000 x g, was dissolved in 4 ml of buffer A. The AS fraction was dialyzed extensively against 200 volumes of buffer A. To 4.2 ml of this dialyzate were added 2.1 ml of alumina Cy gel (50 mg solids per ml) and, after 10 min of gentle mixing, the suspension was centrifuged and the solids discarded. The alumina Cy supernate was applied to a column of DF.AE cellulose (2 x 9 cm) equilibrated with buffer A. The column was washed with buffer A and the activity was recovered in the wash. The active fractions were pooled (15 ml total) and concentrated by The dialyzate negative pressure dialysis against buffer B to a volume of 3 ml. was applied to a column of phosphocellulose (1.5 x 10 cm) equilibrated with buffer B. The column was washed with buffer B (100 ml) and buffer B containing, The activity was first, 0.12 M KCl(50 ml) and, then, 0.2 M KC1 (40 ml). recovered in the latter fractions of the 0.2 M effluent. The active fractions were pooled (10 ml total) and concentrated to 1 ml by negative pressure dialysis against buffer A containing 50% (v/v) glycerol. The phosphocellulose concentrate 50% activity after a period of 2 months. was stored at -20°, retaining
65
Vol. 41, No. 1, 1970
Results
BIOCHEMICAL
and Discussion
Biological
source
listed
in Table
of endonuclease. II
resulted
extracts.
Extracts
from
catalyze
a significant
inactive
extracts
not
to detection
lead
5 min after
phage
here.
or cells
fractionation
mechanism
The endonuclease
it
tested
is
not
known whether
If
the endonuclease
be outside ( attachment
site
bacterial
primarily
A simple
interpretation, gene, tested,
( or
are
adjacent
did
be detected
is not
gene for
encoded
at
determined
the enzyme
in the A chromosome
II
).
cistrons
If
could
segments
the
reside
is of
proper,
present
genes
that
in either
the
on the chromosomes
x~I
deficit
mechanism
and highly
site
extremity
results. 66
infection
deleted
Secondly DNA, site
on the
endonuclease in all
the u
DNA segment.
by simultaneous
gene
adjacer
way on the presence
bacterial
of the biotin
by phage
of the
commonly
in trans
structural
deleted.
of bacterial
induction
on the appearance the
First,
of the x attachment
in a positive
site-proximal
are
stretches
the
of h genes
may depend
- that
amplified
attachment
for
of A genes
left
in common.
by specific
) had no effect
at the
properties
and to the right
induction
however
located
replaced
of an attachment
a presumptive
and XL2
the pbio's
could
endonuclease
( Table
of the prophage
on the deficit
the
chromosomes
Amlo
bacterial
);
two general
one possible
Alternatively,
to supplement
our
genes
Thus,
may depend
phage
of purification
in h bio the longest right40, and outside the region deleted in
the active
following
DNA segments
chromosome.
in the
the
and to the right
phage
incorporating
tested.
of the
missing
the activity
bacterial,
proper,
have
proximal
activity
not
e's.
The km's
host
~51 and J.% did
Cy stage
structural
is
to ~111
or in the bacterial
chromosome
the
the X segment
bacterial
the deleted
in crude
Concentration
action
of this
induces
?, genes
with
breaks.
to the alumina
in the expression
origin.
infecting
activity
infected
of double-strand
mutants, since Lb-2 pbio -11 b* specify the endonuclease are
of the
by each of the hw's
infection.
gene must
deletion
of E. coli
of the endonuclease
cells
of activity.
or bacterial
the relevant
uninfected
production
In particular,
phage
Infection
in appearance
and their
The genetic
wise
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of this for
Attemp
infection
activity
with
( Table
the endonuclease
operon, - is not
I
carried established
is a
by all by
II
BIOCHEMICAL
Vol. 41, No. 1,197O
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table Endonuclease
Infecting
II
activity
phage
of E, -- coli
Specific
activity ( units/mg
of alumina extracts protein )
1. none
CO.5
2. AC-1
<0.5
3. xb -2
CO.5
4. Xint red ---63 5. h bio +0 6. @b&11
ve27-20
'-
16 15
8. Ab2pbioll 9. mixedly infect AC1 or X2
with
Action
of the
less
5% maximum activity
is
between
6.5 and 7.5
in phosphate
buffer.
High
of DNA breakage,
endonuclease Fig.lA increasing revealed
Manganese
seen with in Tris.
the
latter
Cl-.
concentrations
is
enzyme
not an effective cation.
The reaction
thus
being
distinguished
strictly substitute;
The pH optimum proceeds
of sRNA have no effect
the activity
is
for
equally
well
on either from
that
the rate of
I (8). shows the progress proportion
velocity
sedimenting
a shoulder of intact
of reaction
of h DNA molecules
by sedimentation
a peak appears containing
each of the given strains of h phage prepared and assayed as described in
of DNA by the purified
of magnesium.
is
or extent
with were
Breakage
on the presence
reaction
infected extracts
endonuclease.
dependent than
10-14
Aelo
E_, coli 1100 cells were 20 min, cell and, after Materials and Methods.
fraction
1100
with molecules
0.82
with receive
analysis t 0.01
a relative surviving
times
time.
With
sucrose
as fast
decreases,
time,
one or more double-strand
in neutral
sedimentation
increasing
as intact constant
the
shoulder
breaks
of 0.68
molecules, + 0.01.
becomes
as
Initially,
gradients. marker
an
and
As the
more and more
VoL41,No.
1, 1970
prominent
and,
sedimentation neutral
BIOCHEMICAL
eventually, velocity
gradients
after
DNA is more effective least
two peaks,
sedimentation obtained
the profiles 0.60
when nucleolytic
- 0.70
alkaline
become most
that
of intact
denaturation
in resolving
representing
profiles
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
x DNA fragments,
events
are
of this fully
specifying
Sedimentation
through
?, DNA.
fragments.
of reacted Under
these
readily.
reaction
resemble
patterns
position
(9).
do not
in respect
FRACTIONAL
to
a
substrate
conditions,
can be detected
random
FRACTION NUMBER
in the region
and reneutralization
the product
of the products
dense
at
The
It
SIZE
Fig. 1. (A) Sedimentation profiles of X DNA reacted with 30 units of endonuclease for varying periods of time. Reaction was conducted as described in Materials and Methods and samples were taken for analysis in neutral sucrose gradients at 0 min (w), 10 min (o-----o), and 30 min (-). Sedimentation is from right to left. (B) Molecular size distribution of reaction products in neutral (u) and alkaline (o---o) gradients. Reaction was allowed to continue until approximately 30% of substrate molecules had received at least one double-strand break. Samples of the reaction mix were then analyz'ed by sedimentation in neutral and alkaline gradients. 5 to 20% sucrose alkaline gradients contained 0.1 M NaOH, 0.9 M NaCl, 0.01 M EDTA. Sodium hydroxide ( 0.1 M final concentration ) was added to samples prior to layering on alkaline gradients. Calculations for this type of analysis were according to Meselson and Yuan ( 10 ). The ordinate is arithmetic and units are arbitrary. The abcissa represents the ratio of the molecular sizes of DNA products to that of unreacted marker DNA taken as unity. Molecular sizes were calculated from sedimentation constants using Studier's equations ( 12 ). 68
BIOCHEMICAL
Vol. 41, No. 1, 1970
has been difficult intact
to generate
To compare frequencies Fig.
the number
of fragment
1B represents
fragments
" the reaction
h DNA in "pushing
sizes
in neutral
reaction,
approximately
one half
gradients
have
one or more
Fig.
1B thus
lower
suffered
levels
reveal
weight a moderate
of reaction
over
double-strand
extensive
(all
substrate
mechanism to
of enzyme action
Neither have
duplexes
breaks the role
during of this
been determined.
breaks
in DNA and for
mediate
which functions.
in the endonuclease
described
reason
the
Taken
together,
course
for
this
previously
might
with
intact
a greater
density of
cuts.
However, of the
At this
excess
when reaction type
shown in Fig.lB
are
compatible
with
precede
and are
converted
the genetics
have been
that
catalyze
implicated
@&mutants, both
of its
double-strand
(10,13)
conditionally the
genetic
appear
definition
enzyme.
is pleased to acknowledge the excellent assistance of The research was M. Stewart, and Dr. M. Roy Chowdhury. (MA-3325) from the Medical Research Council of Canada.
9, 734 (1964). Meselson, M., J. Mol. Biol., Signer, E. R., &III. Rev. Microbial., 2& 451 (1968). Manly, K. F., Signer, E. R., and Radding, C. M., Virolow, H., J. Mol. Biol., 2, Durwald, H., and Hoffman-Berling,
69
to
defective
References 1. 2. 3. 4.
a
expression
Acknowledgement The author Mrs. S. Dunbar, Mrs. supported by a grant
is
(10,ll).
studied
provide
of
in neutral
h duplexes),
the results
nor
level
double-strand
plotted.
substrate
The results
incisions
in vivo,
Studies here,
appear
of reaction
roles
of the
At this
of curves
single-strand
biological
30-40%
even more marked. pairs
nuclease
were
of intact
broken),
Endonucleases
degradative
physiological
is
in which
gradients
gradients. over
90% survival
breaks
indistinguishable.
double-strand
of single
than
sucrose
breaks , giving
in alkaline
excess
(more
of single
are virtually
fragments
of
of enzyme. the
that
single-strand
20% that
produced,
breaks.
of the molecules
than
breaks
the case where
one or more double-strand
less
concentrations
and alkaline
for
have received
high
weight
and single-strand
such an analysis
molecular
of molecular with
of double
duplexes
of smaller
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
z 177 (1969). 331 (1968).
and a
Vol. 41, No. 1, 1970
5. 6. 7. 8. 9. 10. 11. 12. 13.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Gottesman, M. E., and Yarmolinsky, M. B., Cold Spring Harb. Symp. Quant. Biol., 33, 735 (1968). Goldberg, A. R., and Howe, M., Virology, s, 200 (1969). in Nucleic Acid Research" Thomas, C. A., Jr., and Abelson, J., in 'Procedures eds.) p.553, Harper and Row, 1966. (G. L. Cantoni and D. R. Davies, Lehman, I. R., Roussos, G. G., and Pratt, E. A., J. Biol. Chem., 327, 819 (1962). Litwin, S., Shahn, E., and Kozinski, A. W., J. Virology, 5, 24 (1969). Meselson, M., and Yuan, R., Nature, 217, 1110 (1968). C., J. Mol. Biol., ll, 141 (1965). Bernardi, G., and Cordonnier, Studier, F. W., J. Mol. Biol., 11, 373 (1965). Center, M. S., Studier, F. W., and Richardson, C. C., F'roc. Natl. Acad. Sci. U. S., 65, 242 .(1970).
70