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Reverse transcriptase from avian myeloblastosis virus: A zinc metalloenzyme
Vol.
57, No.
4, 1974
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
REVERSE TRANSCRIPTASE FROM AVIAN MYELOBLASTOSIS
COMMUNICATIONS
VIRUS:
A ZINC METALLOENZYME D. S. Auld,*
H. Kawaguchi,*
D. M. Livingston?
and B. L. Vallee*tt
*The
Biophysics Research Laboratory, Department of Biological Chemistry, Harvard Medical School, Division of Medical Biology, Peter Bent Brigham Hospital, Boston, Massachusetts and the Viral Lymphoma and Leukemia Branch, National Cancer Institute, National Institute of Health, Bethesda, Maryland, 20014 Received
March
4,1974
Previous postulates of a relationship between a zinc enzyme and the leukemic process (1,2) have led to the identification of the RNA dependent DNA polymerase -- reverse transcriptase -- of avian myeloblastosis virus as a zinc metalloenzyme. Microwave induced emission spectrometry provides a microanalytical system capable of measuring precisely lo-l1 to lo-l4 g atoms of metal in microgram amounts of enzyme, orders of magnitude more sensitive than other, conventional methods. The chromatographic fraction with highest enzymatic activity contains 1.5 x lo-11 g atoms of zinc per 1.4 pg of protein, corresponding to 1.7 to 1.9 g atoms of zinc per mole of enzyme for a molecular weight previously determined either as 1.6 or 1.8 x 105. The Zn/activity ratio is constant in the active fractions. detectio~fo;O~f~ rnrq?&"~~e,a;;,;~sent, i.e., at or below their limits of Cower, Agents known to chelate zinc inhibit the enzyme while their nonchelating isomers do not. The data underline the participation of zinc in nucleic acid metabolism and bear importantly upon the lesions which accompany leukemia and zinc deficiency. Introduction Differences
in zinc
led
to the postulate
cal
to the pathophysiology
Many enzymes
(3)
metabolism
that
disturbance
including
The existence
of an RNA dependent
given
new perspectives
other
malignant
zinc
in
tPresent ttTo
address:
zinc
essential
virus
for
(AMV) and other
regarding
of normal
Children's
whom correspondence
dependent
enzyme is
and lymphatic
a biochemical
leukemia
catalytic --
basis
and leukemic
leukocytes
Research
be addressed.
Foundation,
(4,5)
transcriptase
viruses
of leukemic
indications
criti-
activities.
reverse
RNA tumor
first
(1,2).
of E. coli
The earlier
Cancer should
their
DNA polymerase
transformations.
the metabolism
leukocytes
the DNA and RNA polymerases
to contain
myeloblastosis
and leukemic
of a zinc
of myelogenous
are now known
in avian
of normal
(6,7)
Boston,
has
and
of a role (1,2)
--
led
for to
Massachusetts.
BIOCHEMICAL
Vol. 57, No. 4, 1974 the present merase
kinetic
of AMV.
Materials
and spectrographic
The data
purification
that
Concentrations
MnC12,
2.4 nM; DTT,
2 mM; KCl,
at 60 min with Poly
it
of RNA dependent is
a zinc
were
rA and oligo Mass.,
poration.
All
1.11 aliquots obtained
DNA poly-
metalloenzyme.
(lo),
of zinc
to initiate
the
were
were
reagent method
in a series
grade. (9).
0.11
Approximately
M. which
was terminated
Microgram were
Nuclear
Cor-
was measured quantities
analyzed
on 15
of enzyme,
for
zinc,
copper,
discussed
designed Laboratories,
was established
metalloenzymes
Research,
to principles
Dayton
of the method
Collaborative
New England
facilities
Corporation,
of zinc
100 ~1
1 uM; 'HTTP,
Protein
according
instrumental
and accuracy
in any of the
dT12-1g,
from from
chromatography,
Research
used standard
reaction
obtained
70 C per mole,
using
by a modifica-
acid.
on 5 ~1 aliquots but
Monsanto
The validity
0.1 I-IM; oligo
added
exclusion
and manganese
in the
pH 7.8,
Lowry
virus
EDTA was not
M; Tris-Cl,
chemicals
by gel
previously
rA,
dT12-1g
the
(8).
0.10
and 'HTTP,
using
the purified
of agents
10% trichloroacetic
Waltham,
Wooten,
mM; poly
0.2
0.2 pg of protein
from
of Ross et al
steps.
are:
iron
demonstrate
was prepared
of the procedure
assay
studies
and Methods
AMV polymerase tion
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
by Dr.
George
Dayton,
Ohio.
by determination
of known metal
content
and
stoichiometry. Results
and Discussion
With rate is
poly
rA as the template
of the AMV polymerase linear
over
a 20-fold
assay pmoles
(see methods). TTP incorporated Metal
tion
both
complexing reversibly
catalyzed range
of DTT, KC1 and Mn2+ were
and oligo
The Km for per minute
and also
incorporation
as the
inhibit
to result TTP is
in optimal
conditions
the 12
at 25'.
the AMV polymerase
968
for
1 x 10 -5 M and the V is max
dependent,
the
Concentrations
per pig of protein
in a time
initiator,
of TMP at 25' pH 7.8
of enzyme concentration.
chosen
agents
dT12-18
catalyzed
irreversible
reacmanner.
Vol. 57, No. 4, 1974
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table Effect
of Metal
Binding
Dependent
I Agents
DNA Polymerase
Metal Binding
on the Activity*
Concentration Agent
xlO,M
l,lO-phenanthroline
%
40 4
2
101
8
95
4,7-phenanthroline
3
98
8 hydroxyquinoline-5-sulfonate
1
33
5
15
3
30
5
2
*All
rates
measured
at 25".
**Enzyme activities inhibitor, v.
In the absence either
7 x 10
-5
at 25" or 37".
M.
intervals
decreases
At 37',
See methods
in the absence,
of such agents
1 mM, the enzyme is
the At 25',
inhibited
up to 60 minutes
other
conditions.
v c, and in the presence
enzyme is
completely
in the presence
instantaneously
preincubation
for
both
for
60 min-
of l,lO-phenanthroline,
and reversibly
of enzyme with causes
stable
of
with
a KI of
l,lO-phenanthroline
instantaneous
at
and irreversible
in activity.
The metal the
4
2
EDTA
time
v/v ** -c
1
1,7-phenanthroline
utes
(AMV) RNA
inhibition:
complexing its
isomers
properties 1,7
of l,lO-phenanthroline
and 4,7-phenanthroline
969
account neither
bind
for metals
BIOCHEMICAL
Vol. 57, No. 4, 1974 nor
do they
where
inhibit
the nucleotide
l,lO-phenanthroline
number
AND BIOPHYSICAL RESEARCH COMMUNKATIONS
of other,
polymerization
inhibits
structurally
it
activity that turally
agents
bind
indispensible
the presence essential
quantitative Microwave
induced
detection
limits
tion
emission
metal
to us for of either
zinc,
after
removal
tein
contaminants
were
analyzed
in a sharp, enzyme.
for narrow
copper
transition
band with
10 -13
of the most
were
from in
(Table
active
enzyme placed pur ,if ied
II).
on the
preparations
for
This of the
The pre-
the observed
with
were
high
g atoms.
enzyme
inhibi-
deterweight
pro-
emerged
precision
Zinc
(Table
absent,
than
is
II),
i.e.,
to less
activity,
present but
times
higher
activity
is
closely
enzyme employed
for
the
the amounts 0.06
g atoms
7.5 pmole/min/ug
three
970
pre-
v, of 2.1 pmoles/min/ul
virtually
is
means.
Enzyme activity
to 10 -14
correspond
thus,
The 45 ~1 fractions
quantitatively
the purified
the usual
and low molecular
activity,
10 -11
to allow
of enzyme
by this
and protein.
No. 19, column.
of
of enzyme.
amounts
chromatography.
The specific
fraction,
sensitive
and manganese
agents
Cu, Fe and Mn are g atoms,
struc-
of course,
g atoms and,
account
elements
measured
vary
to lo-l4
to 10 -14
could
maximal
quantities
metals,
of enzyme
of highly
activity
amounts
in stoichiometric
detected,
metals,
is,
can extend
seemed feasible
quenching
exclusion
and/or
The demonstration
amounts
on the microgram
and these
by gel
metal.
however,
or iron
of metal
The elements
when absolute
the
purpose
EDTA
interpretation
functional
small
of magnitude
of the AMV polymerase,
mined
mole
this
the
been sufficiently
on very
analyses
e.g.,
a
the polymerase
of such a metal
spectrometry,
by 6 orders
Moreover,
agents,
support
IIB
conditions
hypothesis,
have not
determinations
quantitative
sence
of this
I).
inhibit
unidentified
quantities
procedures
metal
markedly
or group
of stoichiometric
binding
Such data
to a hitherto
to the verification
available
I).
transition
Conventional
cise
(Table
under
(Table
metal
also
instantaneously these
completely
different
and 8-hydroxyquinoline-5-sulfonate
reaction
than
per
protein that
similar molecular
of to that
Vol. 57, No. 4, 1974
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table Analysis
of Gel Exclusion (45 ~1)
Fraction
II Chromatography
Exhibiting
Maximal
Activity*
Protein
Zn/Protein
1-lg
g at/mole
0.7
0.7
1.8
c.001
<.Ol
.06
19
1.5
1.4
1.9
<.OOl
<.Ol
.05
20
1.2
1.1
1.9
<.OOl
<.Ol
.05
Zn
No.
g at x 10
18
11
Cu
determinations
zinc
in 1.4 ug of protein
of zinc
per mole
1.8 x lo5 control
is
cates ing
Zinc
structure
in
function
on the reverse
in the formation a leukemic
on the induction
process, of zinc
of leukemia
to 1.9
found
of DNA from
under
g atoms 1.6 or
(3).
or
For the
to be determined. from AMV show that
RNA templates a hypothesis
acid
of
in catalysis
or both remain
confirming
1.7
to be either
directly
transcriptase
in nucleic are
to from
indirectly
alternatives
of this polymerase are expressed as Analyses were
g atoms
weights
participate
Mn
of 1.5 x lo-l1
corresponds
molecular
these
studies
The roles
II)
may either
and affect
essential
zinc (1,2).
(Table
polymerases,
The present
The detection
of enzyme for
(11-13).
nucleotidyl
zinc
(11-13).
Fe
g at/mole
*Calculations are based on a molecular weight Zinc and protein content of 1.8 x lo5 (13). g atoms or vg per 5 ~1 aliquot, respectively. performed in triplicate.
weight
Fractions
metabolism
and impliof long
stand-
and its
bearing
Todaro,
Edward
study.
Acknowledgements We appreciate Scolnick
and Jeffrey
the advice
and counsel
Ross.
971
of Drs.
George
Vol.
BIOCHEMICAL
57, No. 4, 1974
This Institutes
work
was supported
of Health,
AND
BIOPHYSICAL
by Grant-in-Aid
of the Department
RESEARCH
GM-15003 of Health,
from
Education
COMMUNICATIONS
the National and Welfare.
References 1. Vallee, B.L., Fluharty, R.G. and Gibson, J.G., 2nd, --~ Acta Union Intern. Contre Cancer 6, 869 (1949). 2. Gibson, J.G., 2nd, Vallee, B.L., Fluharty, R.G. and Nelson, J.E., Acta Union Intern. 6 1102 (1950). -Contre ~Cancer -9 3. Vallee, B.L. and W.E.C. Wacker, -The Proteins, Vol. 5, 2nd Ed., H. Neurath (Ed.), Academic Press, New York (1970). 4. Slater, J.P., Mildvan, A.S. and Loeb, L.A., Biochem. Biophys. -*Res Commun. 64, 37 (1968). 5. Scrutton, M.C., Wu, C.W. and Goldthwait, D.A., --Proc. Natl. Acad. --Sci. U.S.A. 68, 2497 (1971). 6. Temin, H.M. and Mizutani, S., Nature 226, 1211 (1970). 7. Baltimore, D., Nature 22, 1209m). 8. Ross, J., ScolnG.F, Todaro, G.J. and Aaronson, S.A., Nature New Biology 231, 163 (1971). A.L. and Randall, R.S., --J. Biol. 9. Lowry, O.M., Rosenbrough, N.T., Farr, Chem. 193, 265 (1951). 10. Kawaguchi, H., Hasegawa, M. and Mizuike, A., Spectrochimica Acta Vol. z, 205 (1972). 11. Gian, D.L., Watson, K.F., Burner, A. and Speigelman, S., Biophys. Biochem. Acta 246, 365 (1971). -__ 12. Hurwitz, J. and Lies, J.P., 2. __ Vir. 8, 116 (1972). 13. Grandgenett, D.P., Gerard, G.F. and Green, M., --Proc. Natl. Acad. m. U.S.A. 3, 230,(1973).
972
57, No.
4, 1974
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
REVERSE TRANSCRIPTASE FROM AVIAN MYELOBLASTOSIS
COMMUNICATIONS
VIRUS:
A ZINC METALLOENZYME D. S. Auld,*
H. Kawaguchi,*
D. M. Livingston?
and B. L. Vallee*tt
*The
Biophysics Research Laboratory, Department of Biological Chemistry, Harvard Medical School, Division of Medical Biology, Peter Bent Brigham Hospital, Boston, Massachusetts and the Viral Lymphoma and Leukemia Branch, National Cancer Institute, National Institute of Health, Bethesda, Maryland, 20014 Received
March
4,1974
Previous postulates of a relationship between a zinc enzyme and the leukemic process (1,2) have led to the identification of the RNA dependent DNA polymerase -- reverse transcriptase -- of avian myeloblastosis virus as a zinc metalloenzyme. Microwave induced emission spectrometry provides a microanalytical system capable of measuring precisely lo-l1 to lo-l4 g atoms of metal in microgram amounts of enzyme, orders of magnitude more sensitive than other, conventional methods. The chromatographic fraction with highest enzymatic activity contains 1.5 x lo-11 g atoms of zinc per 1.4 pg of protein, corresponding to 1.7 to 1.9 g atoms of zinc per mole of enzyme for a molecular weight previously determined either as 1.6 or 1.8 x 105. The Zn/activity ratio is constant in the active fractions. detectio~fo;O~f~ rnrq?&"~~e,a;;,;~sent, i.e., at or below their limits of Cower, Agents known to chelate zinc inhibit the enzyme while their nonchelating isomers do not. The data underline the participation of zinc in nucleic acid metabolism and bear importantly upon the lesions which accompany leukemia and zinc deficiency. Introduction Differences
in zinc
led
to the postulate
cal
to the pathophysiology
Many enzymes
(3)
metabolism
that
disturbance
including
The existence
of an RNA dependent
given
new perspectives
other
malignant
zinc
in
tPresent ttTo
address:
zinc
essential
virus
for
(AMV) and other
regarding
of normal
Children's
whom correspondence
dependent
enzyme is
and lymphatic
a biochemical
leukemia
catalytic --
basis
and leukemic
leukocytes
Research
be addressed.
Foundation,
(4,5)
transcriptase
viruses
of leukemic
indications
criti-
activities.
reverse
RNA tumor
first
(1,2).
of E. coli
The earlier
Cancer should
their
DNA polymerase
transformations.
the metabolism
leukocytes
the DNA and RNA polymerases
to contain
myeloblastosis
and leukemic
of a zinc
of myelogenous
are now known
in avian
of normal
(6,7)
Boston,
has
and
of a role (1,2)
--
led
for to
Massachusetts.
BIOCHEMICAL
Vol. 57, No. 4, 1974 the present merase
kinetic
of AMV.
Materials
and spectrographic
The data
purification
that
Concentrations
MnC12,
2.4 nM; DTT,
2 mM; KCl,
at 60 min with Poly
it
of RNA dependent is
a zinc
were
rA and oligo Mass.,
poration.
All
1.11 aliquots obtained
DNA poly-
metalloenzyme.
(lo),
of zinc
to initiate
the
were
were
reagent method
in a series
grade. (9).
0.11
Approximately
M. which
was terminated
Microgram were
Nuclear
Cor-
was measured quantities
analyzed
on 15
of enzyme,
for
zinc,
copper,
discussed
designed Laboratories,
was established
metalloenzymes
Research,
to principles
Dayton
of the method
Collaborative
New England
facilities
Corporation,
of zinc
100 ~1
1 uM; 'HTTP,
Protein
according
instrumental
and accuracy
in any of the
dT12-1g,
from from
chromatography,
Research
used standard
reaction
obtained
70 C per mole,
using
by a modifica-
acid.
on 5 ~1 aliquots but
Monsanto
The validity
0.1 I-IM; oligo
added
exclusion
and manganese
in the
pH 7.8,
Lowry
virus
EDTA was not
M; Tris-Cl,
chemicals
by gel
previously
rA,
dT12-1g
the
(8).
0.10
and 'HTTP,
using
the purified
of agents
10% trichloroacetic
Waltham,
Wooten,
mM; poly
0.2
0.2 pg of protein
from
of Ross et al
steps.
are:
iron
demonstrate
was prepared
of the procedure
assay
studies
and Methods
AMV polymerase tion
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
by Dr.
George
Dayton,
Ohio.
by determination
of known metal
content
and
stoichiometry. Results
and Discussion
With rate is
poly
rA as the template
of the AMV polymerase linear
over
a 20-fold
assay pmoles
(see methods). TTP incorporated Metal
tion
both
complexing reversibly
catalyzed range
of DTT, KC1 and Mn2+ were
and oligo
The Km for per minute
and also
incorporation
as the
inhibit
to result TTP is
in optimal
conditions
the 12
at 25'.
the AMV polymerase
968
for
1 x 10 -5 M and the V is max
dependent,
the
Concentrations
per pig of protein
in a time
initiator,
of TMP at 25' pH 7.8
of enzyme concentration.
chosen
agents
dT12-18
catalyzed
irreversible
reacmanner.
Vol. 57, No. 4, 1974
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table Effect
of Metal
Binding
Dependent
I Agents
DNA Polymerase
Metal Binding
on the Activity*
Concentration Agent
xlO,M
l,lO-phenanthroline
%
40 4
2
101
8
95
4,7-phenanthroline
3
98
8 hydroxyquinoline-5-sulfonate
1
33
5
15
3
30
5
2
*All
rates
measured
at 25".
**Enzyme activities inhibitor, v.
In the absence either
7 x 10
-5
at 25" or 37".
M.
intervals
decreases
At 37',
See methods
in the absence,
of such agents
1 mM, the enzyme is
the At 25',
inhibited
up to 60 minutes
other
conditions.
v c, and in the presence
enzyme is
completely
in the presence
instantaneously
preincubation
for
both
for
60 min-
of l,lO-phenanthroline,
and reversibly
of enzyme with causes
stable
of
with
a KI of
l,lO-phenanthroline
instantaneous
at
and irreversible
in activity.
The metal the
4
2
EDTA
time
v/v ** -c
1
1,7-phenanthroline
utes
(AMV) RNA
inhibition:
complexing its
isomers
properties 1,7
of l,lO-phenanthroline
and 4,7-phenanthroline
969
account neither
bind
for metals
BIOCHEMICAL
Vol. 57, No. 4, 1974 nor
do they
where
inhibit
the nucleotide
l,lO-phenanthroline
number
AND BIOPHYSICAL RESEARCH COMMUNKATIONS
of other,
polymerization
inhibits
structurally
it
activity that turally
agents
bind
indispensible
the presence essential
quantitative Microwave
induced
detection
limits
tion
emission
metal
to us for of either
zinc,
after
removal
tein
contaminants
were
analyzed
in a sharp, enzyme.
for narrow
copper
transition
band with
10 -13
of the most
were
from in
(Table
active
enzyme placed pur ,if ied
II).
on the
preparations
for
This of the
The pre-
the observed
with
were
high
g atoms.
enzyme
inhibi-
deterweight
pro-
emerged
precision
Zinc
(Table
absent,
than
is
II),
i.e.,
to less
activity,
present but
times
higher
activity
is
closely
enzyme employed
for
the
the amounts 0.06
g atoms
7.5 pmole/min/ug
three
970
pre-
v, of 2.1 pmoles/min/ul
virtually
is
means.
Enzyme activity
to 10 -14
correspond
thus,
The 45 ~1 fractions
quantitatively
the purified
the usual
and low molecular
activity,
10 -11
to allow
of enzyme
by this
and protein.
No. 19, column.
of
of enzyme.
amounts
chromatography.
The specific
fraction,
sensitive
and manganese
agents
Cu, Fe and Mn are g atoms,
struc-
of course,
g atoms and,
account
elements
measured
vary
to lo-l4
to 10 -14
could
maximal
quantities
metals,
of enzyme
of highly
activity
amounts
in stoichiometric
detected,
metals,
is,
can extend
seemed feasible
quenching
exclusion
and/or
The demonstration
amounts
on the microgram
and these
by gel
metal.
however,
or iron
of metal
The elements
when absolute
the
purpose
EDTA
interpretation
functional
small
of magnitude
of the AMV polymerase,
mined
mole
this
the
been sufficiently
on very
analyses
e.g.,
a
the polymerase
of such a metal
spectrometry,
by 6 orders
Moreover,
agents,
support
IIB
conditions
hypothesis,
have not
determinations
quantitative
sence
of this
I).
inhibit
unidentified
quantities
procedures
metal
markedly
or group
of stoichiometric
binding
Such data
to a hitherto
to the verification
available
I).
transition
Conventional
cise
(Table
under
(Table
metal
also
instantaneously these
completely
different
and 8-hydroxyquinoline-5-sulfonate
reaction
than
per
protein that
similar molecular
of to that
Vol. 57, No. 4, 1974
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table Analysis
of Gel Exclusion (45 ~1)
Fraction
II Chromatography
Exhibiting
Maximal
Activity*
Protein
Zn/Protein
1-lg
g at/mole
0.7
0.7
1.8
c.001
<.Ol
.06
19
1.5
1.4
1.9
<.OOl
<.Ol
.05
20
1.2
1.1
1.9
<.OOl
<.Ol
.05
Zn
No.
g at x 10
18
11
Cu
determinations
zinc
in 1.4 ug of protein
of zinc
per mole
1.8 x lo5 control
is
cates ing
Zinc
structure
in
function
on the reverse
in the formation a leukemic
on the induction
process, of zinc
of leukemia
to 1.9
found
of DNA from
under
g atoms 1.6 or
(3).
or
For the
to be determined. from AMV show that
RNA templates a hypothesis
acid
of
in catalysis
or both remain
confirming
1.7
to be either
directly
transcriptase
in nucleic are
to from
indirectly
alternatives
of this polymerase are expressed as Analyses were
g atoms
weights
participate
Mn
of 1.5 x lo-l1
corresponds
molecular
these
studies
The roles
II)
may either
and affect
essential
zinc (1,2).
(Table
polymerases,
The present
The detection
of enzyme for
(11-13).
nucleotidyl
zinc
(11-13).
Fe
g at/mole
*Calculations are based on a molecular weight Zinc and protein content of 1.8 x lo5 (13). g atoms or vg per 5 ~1 aliquot, respectively. performed in triplicate.
weight
Fractions
metabolism
and impliof long
stand-
and its
bearing
Todaro,
Edward
study.
Acknowledgements We appreciate Scolnick
and Jeffrey
the advice
and counsel
Ross.
971
of Drs.
George
Vol.
BIOCHEMICAL
57, No. 4, 1974
This Institutes
work
was supported
of Health,
AND
BIOPHYSICAL
by Grant-in-Aid
of the Department
RESEARCH
GM-15003 of Health,
from
Education
COMMUNICATIONS
the National and Welfare.
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