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Thermolysin: A zinc metalloenzyme
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 37, No. 2, 1969
A ZINC METALLOENZYME
THERMOLYSIN: Samuel A. Latt*,
Barton
Holmquist-
and Bert
L. Vallee
The Biophysics Research Laboratory, Department of Biological Chemistry, Harvard Medical School, Division of Medical Biology, Peter Bent Brigham Hospital, Boston, Massachusetts
Received
August
19, 1969
Metal analyses and inhibitor studies have shown that thermolysin, a neutral protease from B. thermoproteolyticus, is a zinc metalloenzyme. The relevance of this fiaing to the active site characteristics of other bacterial neutral proteases and to those of alkaline proteases is considered. A catalytically
INTRODUCTION: active
sites
of a number of proteolytic
endopeptidase
specificity
chemical
(5,6,7,8)
as to its
demonstrate
metal
that
content
thermolysin
and Calbiochem
crystallized high
three
pH, followed
is a zinc
Thermolysin
or more times
before
+I-
Fellow
+Fellow
of the National
Institute
of the National
Cancer
use,
This either
at neutrality
the metal
by Grant-in-Aid of the Department
333
though
no
studies
material
was re-
by dissolving (2)
at
or by dissolving
to low ionic
content
(Osaka,
strength
and the specific
act-
GM-15003 from the National of Health, Education and Welfare.
of Arthritis Institute
(6),
from Diawa Kasei
pH and dialyzing
Both
crystallization.
as
stabilized
The present
California).
by recrystallization
of Health
as well
metalloenzyme.
was obtained
(Los Angeles,
an
recently
The enzyme is
as yet.
at the
Thermolysin,
properties'(3,4),
are on record
+ This work was supported Institutes
(1).
has been purified
and kinetic
the enzyme in 5 M NaBr at neutral to promote
enzymes
by EDTA and l,lO-phenanthroline
MATERIALS AND METHODS: Japan)
atom has been found
have been described.
by Ca 2+ (2) and inhibited data
zinc
from -B. thermoproteolyticus,
(21, and some of its its
essential
and Metabolic
Diseases
Vol. 37, No. 2, 1969
ivities
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of material Metal
obtained
analyses
(9) and by atomic the basis muffle
on the
ing
Values
samples
amide
observed
0.01
M Ca2+ , pH 7.5,
p = O.lM
tion
(10 half
in
ed as k = kobsd/[E] lcm = 17.65 OD280
for
Inhibition
in M-'min
studies
of stock
solution
of substrate
furylacryloylglycine
All several extraction.
and appropriate
and inhibitor. after
(methanol-CHC13,
Acid
1:9)
use.
cleaned precautions
were proportional
containing
The first
readings
weight
Products
by the
of absorbance of the hydrolysis, by thin
silica grade
Buffers
were rendered
metal-free
glassware
or nalgene
tubes
37,500(3).
an equilibrated
were of reagent
334
are expressbased on
were identified
metal
to comple-
were performed
on fluorescent
to prevent
lives.
and were followed
agents
Km,
in 0.05 M Tris,
cuvette
amide,
and chemicals
before
constant,
Rate constants
enzyme addition.
and leucine
inhibitors times
binding
utiliz-
California).
two half
of an enzyme of molecular metal
for
the substrate
enzyme concentration
enzyme to a reaction
one minute
chromatography
with
rate
at 25'
with
and
of furylacryloyl-
at least
experiments.
a 1% solution
addition
were taken
-1
material
communication),
below
were performed
(NaCl)
several
for
order
Reactions
to enzyme concentration.
personal
of 1 mM, well
first
were similar
Company, Los Angeles,
order
an electric
based on a procedure
at 345 mu on hydrolysis
first
on
enzyme (3).
Feder,
Chemical
in
analyses
on native
spectrophotometrically
were
lives)
of zinc
of the
(12;
spectrography
Data are reported
spectrometry
concentrations
the
emission
the same.
were ashed at 450'
The results
(Cycle
of hydrolysis
of kobsd,
which
coefficient
substrate
rates
(10,ll).
in absorbance
glycyl-L-leucine
all
spectrometry
of -B. subtilis
the decrease
are virtually
by spark
absorption
was assayed
procedure
both
analysis.
extinction
protease
At initial
for
by atomic
Activity neutral
absorption
before
when performed based
were performed
of dry weight
furnace
by either
gel
layer (Eastman).
or recrystallized by dithizone
were used throughout
contamination
were
observed(1
1).
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 37, No. 2, 1969
RESULTS:
The metal
ed thennolysin ug/g
zinc,
other
3800 ugfg
metals
found
in solution
incubation Figure
of five
are shown in Table
to reaction
Preparations
mixtures
1 shows the effect
throline,
thioglycolic
pKI for
2,2'-bipyridine,
cyanide
were
the
about
2000
concentration
of
3.1,
these
agents
of increasing acid
gave identical
Spectrographic
The addition
Analyses
of l,lO-phenanValues'
mercaptoacetic
respectively.
pre-
results.
on enzyme activity.
mercaptoethylamine, 2.4 and 2.2,
zinc
Prolonged
concentrations
and imidazole
up to 0.08 M.
known to bind
instantaneously.
Table Emission
of recrystalliz-
contained
of agents
hydrolysis
of the enzyme with
at concentrations
I.
preparations
on the ave.rage,and
calcium
inhibited
3.4,
different
was insignificant.
The addition ions
analyses
Azide of zinc
did
ions
acid,
and
not
inhibit
to enzyme solu-
I. of Three
Times Recrysallized
Thermolysin Metal
J -Zn
Content
(ug/g)
-Ca
-Fe
&
E
*
1
Sample 1
2100 + 200
3400
*
2
2000 5 300
3900
310
50
*
3
2000 2 300
3500
350
100
20
4
1850 + 200
4000
80
25
2
5
1900 Ifi 300
4400
100
20
*
7 Includes atomic absorption ments were performed at least metals were measured at least are the averages.
measurements. All zinc measurein quadruplicate; all other in duplicate. The values given
* = Not detected; also Cd, Co, Cr, Mg, Mn, MO, Ni, Pb, Sr. Copper was not determined due to the method employed (9). 335
of
Vol. 37, No. 2, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure 1: Effect of Metal Binding Agents on the Activity Thermolysin. Initial substrate concentration was 1 m M in M Tris-Cl, .Ol M CaClz, and NaCl to ionic strength of 0.1 25'. Activity is expressed as 100 times the ratio of the inhibited rate constant, kI to the control kc, determined described under Materials and Methods. kc under the above conditions is 9 -+ 1 x 105M-1min"~1.
tions, in
complete
which with
fully
inhibited reactivation.
reactivated the effect Dialysis
by l,lO-phenanthroline
of excess versus
three
0.05 M HEPES, pH 7, 0.4
zinc
ions
changes
M NaCl,
as
or 2,2'-bipyridine,
Concentrations
the enzyme completely,
of .05 at
of zinc caused
on the native of 0.001
ions,
resulted
in excess
inhibition,
of those
in agreement
enzyme.
M l,lO-phenanthroline,
0.01 M CaC12 for
eight
hours
each,
0 MOLES kn /37,500
g2ENZ.
to Apothermolysin upon Figure 2: Return of Enzymatic Activity Apothermolysin, prepared as described in Readdition of Zinc. the text, contained five per cent of the initial zinc content, and possessed six per cent of the activity of the native enzyme. Activity data are expressed at the ratio of kZn, the rate observed with zinc added to the apoenzyme, to k c, the rate of the native enzyme. 336
Vol. 37, No. 2, 1969
followed each,
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
by dialysis reduced
of the
enzymatic
control.
ed by the
against
Moreover,
zinc
the
addition,
at least
a zinc
from
for
(9,14),
number of chelating
ions
Thus, zinc. (Figure
is
essential
agent
2).
agents,
While metal
ions
for
single
enzymes
has been reported subunit the
zinc
structure. content
the
but
it
1).
from
IIB
and was inactive. and removal
containing
is not
calcium,
of experimental
error.
in catalytic
activity.
of the number of with
molecular
known whether
at present (Table
337
it
would I)
relative
weight
or not
of zinc
ease,
metalloof 37,500
the enzyme has
seem advisable
or moles
of
activity
when i'nvest'igatingmultichain
a preliminary
zinc
of the
atom restores
the stoichiometry
ions
thereby
dialysis
interaction
directly
gram A
Further,
zinc
has been established
in vg/gm
contains
enzyme.
inhibitors,
contain
in buffers
proteins
molecule
Hence, either
not
seem involved
For thermolysin (3),
for
have
thermolysin
and group
(Figure
the limits
have been problematic
(15).
at
2000 ug per
of the
of the metal
within
chain
about
resulting
did
and assayed
do not
atoms per protein
such efforts
enzyme zinc
the reincorporation
that
transition
the enzyme through
When stored
calcium
upon
consistently
function
thermolysin
The product
inhibits
establish
averaging
known to bind
inhibit
the apoenzyme was inactive Thus,
grams
in such buffers
thermolysin
to the
l,lO-phenanthroline
Further,
37,500
of metalloenzyme
data
Recrystallized
the inhibition.
this
per
to 5%
reestablish-
of activity
the identification
compete with
enzyme against
content
was completely
on storage
and the present
effectively
effectively
reversing
hours
two weeks.
The metal
in solution,
eight
6% and zinc
by regeneration
apoenzyme was stable
metalloenzyme.
I).
than
for
1 gram atom of zinc
1700 to 2300 pg per gram of zinc,
(Table
of buffer
2, activity
as judged
The criteria
been delineated is
to less
of approximately
of apoenzyme.
DISCUSSION:
activity
changes
As shown in Figure
addition
5" C for
three
to express per
375500
Vol. 37, No. 2, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
grams of thermolysin structure
(Figure
of thermolysin
is
enzyme can be assigned in view ently
of the in
there
all
is
large
enzyme,
(15)
and,
metal
for
hence,
definition
as to the
peptidases
and their
Similarly,
the neutral
proteases.
throline,
is
inhibited
which
well
reveal
peptidases of their
residues
(21).
active
bacterial differ sites,
enzymes of mammalian characteristic themselves preservation
both
of a zinc
neutral
study
proteolytic by the carboxy-
and &
zinc
megatherium
megatherium,mega-
may also
proteases
at least
be a metallofrom bacteria
contrasting
have been found
in pH optimum
from
and l,lO-phenan-
protease
contain
(16).
of bacterial
from L
features,
with
two classes
and the detailed
seryl
chemical
whi.le
mechanism properties
33%
residue
some exopeptidases of action. at the
of
chemistries
Here,
a DFP reactive
alka-
to have DFP
of the proteolytic
endopeptidases
purposes
more precise
and that
(18)
of neutral
generally
atom in their
of distinctive
(17)
That
of
rigor-
in some ways reminiscent pancreas.
of certain
function
aminopeptidases
A. oryzae
strains
in
enzyme.
by EDTA, 2,2'-bipyridine
which
which
await
examples
such common chemical
certain
Thus,
must
enzymes as exemplified
this
Though
or both
number of mammalian
proteases.
proteases
seryl
structural,
of the
now constitute
that
2+
also
consist-
described.
of Ca
from -B. subtilis
a systematic
Thus,
bacterial
reactive
suggested
here
of calcium
S.griseus,
neutral
enzyme (20).
line
(16)
imperative
have been found
and by certain
protease
contain
theriopeptidase,
role
precursors
appear
of zinc/
have to be investigated
architecture
-B. aeruginosa, also
will
to be zinc
-B. thermoproteolyticus
which
functional,
an increasing
years,
would
participation
such possibilities
of the protein
a stoichiometry
of thermolysin
can serve
enzymes have been found
might
of calcium
of the molecular
In recent
(19,20)
This
the direct
atoms
investigation
before
definitively.
of the preparations
Conjectures
ously.
A detailed
required
amounts
no evidence
the
2).
Could active
is avail
the sites
of
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 37, No. 2, 1969
two types contain
of proteolytic information
and mechanisms and tertiary e.g.
Ca
2+
structure
elucidation
It
both
could
to the evolution
of the details
seryl studies of these
of their
changes
dependent
to modulate
forms
of enzymatic
be that
those
and the active enzymological
and higher
the evolution
including
, have been employed
Comparative
relevance
concerning
of action?
atom in one class iant.
enzymes in lower
secondary
such as,
to which
such lines
classes
mechanism
in primary,
in the other
along
specificities
upon ions
functions
residue
of life
the
zinc
are invarmight
have
of enzymes and the
of action.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21.
Vallee,
B. L. and Wacker, W. E. C., in "The Proteins," Vo1.5, 8. Neurath, Ed., Academic Press, New York, New York, in press. Tech. do, 346 (1962). Endo, S., J. Fermentation Chem. 241, 5919 (1966). Ohta, Y., Ogura, Y. and Wada, A., J. Biol. Chem. 242, 509 (1967). Ohta, Y., J. Biol. Matsubara, I-l., Singer, A., Sasaki, R. and Jukes, T. A., Biochem. Biophys. Res. Commun. 21, 242 (1965). Morihara, K. and Tsuzuki, II., Biochim. Biophys. Acta 118, 215 (1966). I-I. and Oka, T., Arch Biochem. Biophys. 123, Morihara, K., Tsuzuki, 572 (1968). A. and Sasaki, R. Biochem. Biophys. Res. Commun. Matsubara, II., Singer, 2, 719 (1969). Vallee, B. L., Adv. Prot. Chem. lo, 317 (1955). Fuwa, K. and Vallee, B. L., Anal. Chem. 35, 942 (1963). P., McKay, R. and Vallee, Fuwa, K., Pulido, B. L., Anal. Chem. 36, 2407 (1964). Res. Commun. 2, 326 (1968). Feder, J., Biochem. Biophys. Thiers, R. T., in Methods of Bdochemical Analysis, Vol. 5, D. Glick, Publishers, Inc., New York, New York, p. 273 Ed., Interscience (1957). Vallee, B. L., in "The Enzymes," P. D. Boyer, H. Lardy and K. Myrback, Eds., Vol. 3, Academic Press, New York, London, p. 225 (1960). Drum, D. E. and Vallee, B. L., in press. Vallee, B. L. and Latt, S. A., in Dress. McCann, J. D., Tsuru, D. and Yasunobu, K., J. Biol. Chem. 239, 3706 (1964). Morihara, K., Biochem. Biophys. Res. Commun. 26, 656 (1967). Millet, J. and Acher, R., Biochim. Biophys. Acta 151, 302 (1968). Sot. Chim. Biol. 5l, 61 (1969). Millet, J., J. Bull. Vallee, B. L. and Riordan, J. F., Ann. Rev. Biochem. 2, 733 (1969).
339
Vol. 37, No. 2, 1969
A ZINC METALLOENZYME
THERMOLYSIN: Samuel A. Latt*,
Barton
Holmquist-
and Bert
L. Vallee
The Biophysics Research Laboratory, Department of Biological Chemistry, Harvard Medical School, Division of Medical Biology, Peter Bent Brigham Hospital, Boston, Massachusetts
Received
August
19, 1969
Metal analyses and inhibitor studies have shown that thermolysin, a neutral protease from B. thermoproteolyticus, is a zinc metalloenzyme. The relevance of this fiaing to the active site characteristics of other bacterial neutral proteases and to those of alkaline proteases is considered. A catalytically
INTRODUCTION: active
sites
of a number of proteolytic
endopeptidase
specificity
chemical
(5,6,7,8)
as to its
demonstrate
metal
that
content
thermolysin
and Calbiochem
crystallized high
three
pH, followed
is a zinc
Thermolysin
or more times
before
+I-
Fellow
+Fellow
of the National
Institute
of the National
Cancer
use,
This either
at neutrality
the metal
by Grant-in-Aid of the Department
333
though
no
studies
material
was re-
by dissolving (2)
at
or by dissolving
to low ionic
content
(Osaka,
strength
and the specific
act-
GM-15003 from the National of Health, Education and Welfare.
of Arthritis Institute
(6),
from Diawa Kasei
pH and dialyzing
Both
crystallization.
as
stabilized
The present
California).
by recrystallization
of Health
as well
metalloenzyme.
was obtained
(Los Angeles,
an
recently
The enzyme is
as yet.
at the
Thermolysin,
properties'(3,4),
are on record
+ This work was supported Institutes
(1).
has been purified
and kinetic
the enzyme in 5 M NaBr at neutral to promote
enzymes
by EDTA and l,lO-phenanthroline
MATERIALS AND METHODS: Japan)
atom has been found
have been described.
by Ca 2+ (2) and inhibited data
zinc
from -B. thermoproteolyticus,
(21, and some of its its
essential
and Metabolic
Diseases
Vol. 37, No. 2, 1969
ivities
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of material Metal
obtained
analyses
(9) and by atomic the basis muffle
on the
ing
Values
samples
amide
observed
0.01
M Ca2+ , pH 7.5,
p = O.lM
tion
(10 half
in
ed as k = kobsd/[E] lcm = 17.65 OD280
for
Inhibition
in M-'min
studies
of stock
solution
of substrate
furylacryloylglycine
All several extraction.
and appropriate
and inhibitor. after
(methanol-CHC13,
Acid
1:9)
use.
cleaned precautions
were proportional
containing
The first
readings
weight
Products
by the
of absorbance of the hydrolysis, by thin
silica grade
Buffers
were rendered
metal-free
glassware
or nalgene
tubes
37,500(3).
an equilibrated
were of reagent
334
are expressbased on
were identified
metal
to comple-
were performed
on fluorescent
to prevent
lives.
and were followed
agents
Km,
in 0.05 M Tris,
cuvette
amide,
and chemicals
before
constant,
Rate constants
enzyme addition.
and leucine
inhibitors times
binding
utiliz-
California).
two half
of an enzyme of molecular metal
for
the substrate
enzyme concentration
enzyme to a reaction
one minute
chromatography
with
rate
at 25'
with
and
of furylacryloyl-
at least
experiments.
a 1% solution
addition
were taken
-1
material
communication),
below
were performed
(NaCl)
several
for
order
Reactions
to enzyme concentration.
personal
of 1 mM, well
first
were similar
Company, Los Angeles,
order
an electric
based on a procedure
at 345 mu on hydrolysis
first
on
enzyme (3).
Feder,
Chemical
in
analyses
on native
spectrophotometrically
were
lives)
of zinc
of the
(12;
spectrography
Data are reported
spectrometry
concentrations
the
emission
the same.
were ashed at 450'
The results
(Cycle
of hydrolysis
of kobsd,
which
coefficient
substrate
rates
(10,ll).
in absorbance
glycyl-L-leucine
all
spectrometry
of -B. subtilis
the decrease
are virtually
by spark
absorption
was assayed
procedure
both
analysis.
extinction
protease
At initial
for
by atomic
Activity neutral
absorption
before
when performed based
were performed
of dry weight
furnace
by either
gel
layer (Eastman).
or recrystallized by dithizone
were used throughout
contamination
were
observed(1
1).
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 37, No. 2, 1969
RESULTS:
The metal
ed thennolysin ug/g
zinc,
other
3800 ugfg
metals
found
in solution
incubation Figure
of five
are shown in Table
to reaction
Preparations
mixtures
1 shows the effect
throline,
thioglycolic
pKI for
2,2'-bipyridine,
cyanide
were
the
about
2000
concentration
of
3.1,
these
agents
of increasing acid
gave identical
Spectrographic
The addition
Analyses
of l,lO-phenanValues'
mercaptoacetic
respectively.
pre-
results.
on enzyme activity.
mercaptoethylamine, 2.4 and 2.2,
zinc
Prolonged
concentrations
and imidazole
up to 0.08 M.
known to bind
instantaneously.
Table Emission
of recrystalliz-
contained
of agents
hydrolysis
of the enzyme with
at concentrations
I.
preparations
on the ave.rage,and
calcium
inhibited
3.4,
different
was insignificant.
The addition ions
analyses
Azide of zinc
did
ions
acid,
and
not
inhibit
to enzyme solu-
I. of Three
Times Recrysallized
Thermolysin Metal
J -Zn
Content
(ug/g)
-Ca
-Fe
&
E
*
1
Sample 1
2100 + 200
3400
*
2
2000 5 300
3900
310
50
*
3
2000 2 300
3500
350
100
20
4
1850 + 200
4000
80
25
2
5
1900 Ifi 300
4400
100
20
*
7 Includes atomic absorption ments were performed at least metals were measured at least are the averages.
measurements. All zinc measurein quadruplicate; all other in duplicate. The values given
* = Not detected; also Cd, Co, Cr, Mg, Mn, MO, Ni, Pb, Sr. Copper was not determined due to the method employed (9). 335
of
Vol. 37, No. 2, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure 1: Effect of Metal Binding Agents on the Activity Thermolysin. Initial substrate concentration was 1 m M in M Tris-Cl, .Ol M CaClz, and NaCl to ionic strength of 0.1 25'. Activity is expressed as 100 times the ratio of the inhibited rate constant, kI to the control kc, determined described under Materials and Methods. kc under the above conditions is 9 -+ 1 x 105M-1min"~1.
tions, in
complete
which with
fully
inhibited reactivation.
reactivated the effect Dialysis
by l,lO-phenanthroline
of excess versus
three
0.05 M HEPES, pH 7, 0.4
zinc
ions
changes
M NaCl,
as
or 2,2'-bipyridine,
Concentrations
the enzyme completely,
of .05 at
of zinc caused
on the native of 0.001
ions,
resulted
in excess
inhibition,
of those
in agreement
enzyme.
M l,lO-phenanthroline,
0.01 M CaC12 for
eight
hours
each,
0 MOLES kn /37,500
g2ENZ.
to Apothermolysin upon Figure 2: Return of Enzymatic Activity Apothermolysin, prepared as described in Readdition of Zinc. the text, contained five per cent of the initial zinc content, and possessed six per cent of the activity of the native enzyme. Activity data are expressed at the ratio of kZn, the rate observed with zinc added to the apoenzyme, to k c, the rate of the native enzyme. 336
Vol. 37, No. 2, 1969
followed each,
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
by dialysis reduced
of the
enzymatic
control.
ed by the
against
Moreover,
zinc
the
addition,
at least
a zinc
from
for
(9,14),
number of chelating
ions
Thus, zinc. (Figure
is
essential
agent
2).
agents,
While metal
ions
for
single
enzymes
has been reported subunit the
zinc
structure. content
the
but
it
1).
from
IIB
and was inactive. and removal
containing
is not
calcium,
of experimental
error.
in catalytic
activity.
of the number of with
molecular
known whether
at present (Table
337
it
would I)
relative
weight
or not
of zinc
ease,
metalloof 37,500
the enzyme has
seem advisable
or moles
of
activity
when i'nvest'igatingmultichain
a preliminary
zinc
of the
atom restores
the stoichiometry
ions
thereby
dialysis
interaction
directly
gram A
Further,
zinc
has been established
in vg/gm
contains
enzyme.
inhibitors,
contain
in buffers
proteins
molecule
Hence, either
not
seem involved
For thermolysin (3),
for
have
thermolysin
and group
(Figure
the limits
have been problematic
(15).
at
2000 ug per
of the
of the metal
within
chain
about
resulting
did
and assayed
do not
atoms per protein
such efforts
enzyme zinc
the reincorporation
that
transition
the enzyme through
When stored
calcium
upon
consistently
function
thermolysin
The product
inhibits
establish
averaging
known to bind
inhibit
the apoenzyme was inactive Thus,
grams
in such buffers
thermolysin
to the
l,lO-phenanthroline
Further,
37,500
of metalloenzyme
data
Recrystallized
the inhibition.
this
per
to 5%
reestablish-
of activity
the identification
compete with
enzyme against
content
was completely
on storage
and the present
effectively
effectively
reversing
hours
two weeks.
The metal
in solution,
eight
6% and zinc
by regeneration
apoenzyme was stable
metalloenzyme.
I).
than
for
1 gram atom of zinc
1700 to 2300 pg per gram of zinc,
(Table
of buffer
2, activity
as judged
The criteria
been delineated is
to less
of approximately
of apoenzyme.
DISCUSSION:
activity
changes
As shown in Figure
addition
5" C for
three
to express per
375500
Vol. 37, No. 2, 1969
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
grams of thermolysin structure
(Figure
of thermolysin
is
enzyme can be assigned in view ently
of the in
there
all
is
large
enzyme,
(15)
and,
metal
for
hence,
definition
as to the
peptidases
and their
Similarly,
the neutral
proteases.
throline,
is
inhibited
which
well
reveal
peptidases of their
residues
(21).
active
bacterial differ sites,
enzymes of mammalian characteristic themselves preservation
both
of a zinc
neutral
study
proteolytic by the carboxy-
and &
zinc
megatherium
megatherium,mega-
may also
proteases
at least
be a metallofrom bacteria
contrasting
have been found
in pH optimum
from
and l,lO-phenan-
protease
contain
(16).
of bacterial
from L
features,
with
two classes
and the detailed
seryl
chemical
whi.le
mechanism properties
33%
residue
some exopeptidases of action. at the
of
chemistries
Here,
a DFP reactive
alka-
to have DFP
of the proteolytic
endopeptidases
purposes
more precise
and that
(18)
of neutral
generally
atom in their
of distinctive
(17)
That
of
rigor-
in some ways reminiscent pancreas.
of certain
function
aminopeptidases
A. oryzae
strains
in
enzyme.
by EDTA, 2,2'-bipyridine
which
which
await
examples
such common chemical
certain
Thus,
must
enzymes as exemplified
this
Though
or both
number of mammalian
proteases.
proteases
seryl
structural,
of the
now constitute
that
2+
also
consist-
described.
of Ca
from -B. subtilis
a systematic
Thus,
bacterial
reactive
suggested
here
of calcium
S.griseus,
neutral
enzyme (20).
line
(16)
imperative
have been found
and by certain
protease
contain
theriopeptidase,
role
precursors
appear
of zinc/
have to be investigated
architecture
-B. aeruginosa, also
will
to be zinc
-B. thermoproteolyticus
which
functional,
an increasing
years,
would
participation
such possibilities
of the protein
a stoichiometry
of thermolysin
can serve
enzymes have been found
might
of calcium
of the molecular
In recent
(19,20)
This
the direct
atoms
investigation
before
definitively.
of the preparations
Conjectures
ously.
A detailed
required
amounts
no evidence
the
2).
Could active
is avail
the sites
of
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 37, No. 2, 1969
two types contain
of proteolytic information
and mechanisms and tertiary e.g.
Ca
2+
structure
elucidation
It
both
could
to the evolution
of the details
seryl studies of these
of their
changes
dependent
to modulate
forms
of enzymatic
be that
those
and the active enzymological
and higher
the evolution
including
, have been employed
Comparative
relevance
concerning
of action?
atom in one class iant.
enzymes in lower
secondary
such as,
to which
such lines
classes
mechanism
in primary,
in the other
along
specificities
upon ions
functions
residue
of life
the
zinc
are invarmight
have
of enzymes and the
of action.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21.
Vallee,
B. L. and Wacker, W. E. C., in "The Proteins," Vo1.5, 8. Neurath, Ed., Academic Press, New York, New York, in press. Tech. do, 346 (1962). Endo, S., J. Fermentation Chem. 241, 5919 (1966). Ohta, Y., Ogura, Y. and Wada, A., J. Biol. Chem. 242, 509 (1967). Ohta, Y., J. Biol. Matsubara, I-l., Singer, A., Sasaki, R. and Jukes, T. A., Biochem. Biophys. Res. Commun. 21, 242 (1965). Morihara, K. and Tsuzuki, II., Biochim. Biophys. Acta 118, 215 (1966). I-I. and Oka, T., Arch Biochem. Biophys. 123, Morihara, K., Tsuzuki, 572 (1968). A. and Sasaki, R. Biochem. Biophys. Res. Commun. Matsubara, II., Singer, 2, 719 (1969). Vallee, B. L., Adv. Prot. Chem. lo, 317 (1955). Fuwa, K. and Vallee, B. L., Anal. Chem. 35, 942 (1963). P., McKay, R. and Vallee, Fuwa, K., Pulido, B. L., Anal. Chem. 36, 2407 (1964). Res. Commun. 2, 326 (1968). Feder, J., Biochem. Biophys. Thiers, R. T., in Methods of Bdochemical Analysis, Vol. 5, D. Glick, Publishers, Inc., New York, New York, p. 273 Ed., Interscience (1957). Vallee, B. L., in "The Enzymes," P. D. Boyer, H. Lardy and K. Myrback, Eds., Vol. 3, Academic Press, New York, London, p. 225 (1960). Drum, D. E. and Vallee, B. L., in press. Vallee, B. L. and Latt, S. A., in Dress. McCann, J. D., Tsuru, D. and Yasunobu, K., J. Biol. Chem. 239, 3706 (1964). Morihara, K., Biochem. Biophys. Res. Commun. 26, 656 (1967). Millet, J. and Acher, R., Biochim. Biophys. Acta 151, 302 (1968). Sot. Chim. Biol. 5l, 61 (1969). Millet, J., J. Bull. Vallee, B. L. and Riordan, J. F., Ann. Rev. Biochem. 2, 733 (1969).
339