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Differentiation of the tyrosyl groups of ribonuclease A by iodination
Vol. 5, No. 1,1961
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
DIFFERENTIATION OF THE TYROSYLGROUPSOF RIBONUCLEASEA BY IODINATION* Chul-Yung
Cha and Harold A. Scheraga
Department of Chemistry, Received April
Cornell
Ithaca,
N. Y.
19, 1961
Three of the six tyrosyl normal (Shugar, sequence of this offers
University,
residues
1952; Tanford protein
the possibility
of rlbonuclease
et al, 1955).
IS known (Hlrs of locating
normal groups in the polypeptlde matlon about the conformation
Since the amino acid
et al, l%O),
the positions chain,
are ab-
thereby
of the molecule
iodination
of the three providing
ab-
lnfor-
In solution.
EXPERIMENTAL Rlbonuclease the recommendations lodotyrosyl Several
A was lodinated
of Hughes and Straessle
groups without
derivatives
at 10°C at pH 9.4 according
affecting
were prepared
other
to
(1950) to produce diamino acid residues.
with different
degrees of lodl-
nation.++ RESULTS Alkaline carried
Titration
Data:-
out at alkaline
Spectrophotometric
titrations
were
pH at 312 w and 295 ml.l (1O'C) to deter-
mine the number of dllodotyrosyl
and tyrosyl
residues
(Tgble
I).
*This work was supported by research grant No. E-1473 from the National Institute of Allergy and Infectious Diseases of the National Institutes of Health, Public Health Service, and by grant No. G-14792 from the National Science Foundation. **The tyrosyl groups react with iodine at different rates; three groups react rapidly and the remaining ones more slowly. For example, three groups reacted completely In 1.5 hrs. The fourth group was not completely lodinated after 3 hrs. When an amount of Iodine equivalent to six tyrosyl groups was added, two groutis remained un-lodinated even after 25 hrs., the iodine color persisting for this length of time. 67
Vol. 5, No. 1,1961
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE I TITRATION OF DIIODOTYROSYL GROUPS Number of tyrosyl groups equivalent to the amount of iodine added
Derlvatlve A
Change in molar extin;tiz ;;;ff$clent,
Number of tyrosyls
iodlnated*
,
pK*+
15,000
3.1
8.0
B
3 4
18,000
3.8
7.8
C
6
18,800
3.9
7.6
*Based on a value of 4800 er single group of dilodotyroslne in insulin (Qruen et al, 1959P . **The observed pK1s are somewhat higher than that of dilodotyrosine, 6.5, (Qruen et al, 1959) and close to that of monoiodotyrosine, 8.2, (Herrlott, 1948). However, the appearance of the U.V. absorption The high pK1s spectrum indicates that monolodotyroslne is absent. may be due to local Interactions in the lodlnated protein. The titration
at 295 R&Lshowed an increase
3000 between pH 8 and 12.5 In derivatives this
contrlbutlon
of the un-iodinated
At pH 12 and
the abnormal tyrosyl
on standing Is similar
12.5
at room temperature to that of native
U.V. Difference obtained
A, B, and C.
is due to the dilodotyrosyl
to the Ionization
for
in E of about groups rather
abnormal tyrosyl groups ionize
several
groups. Irreversibly
hours.
This behavior
U.V. difference
spectra were
at low pH and compared with those for native 1961).
than
rlbonuclease.
Spectra at Low pH:-
(Hermans and Scheraga,
However,
The difference
spectra
ribonuclease of deriva-
tives A, B, C are similar to each other and to that of the unlodlnated molecule. Since the native protein contains two tyrosylcarboxyl
hydrogen bonds imbedded In hydrophobic
and Scheraga, exist In all
1961),
In derivatives 3 derivatives;
regions
it appears that these interactions A, B, and C. it
Precipitation
seems that the solubillty
Is decreased at low pH by lodinatlon. 68
(Hermans still
occurs below pH 1 of ribonuclease
BIOCHEMICAL
Vol. 5, No. 1,196l
U.V. Absorption tives
Spectra:-
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
The U.V. abeorption
spectra
of deriva-
A and C were examined between 270 w and 3aO w at pH 10.5
and 11.5, respectively, 305 w according tyrosinee
to search, for monolodotyrosine
to Herrlott,
(peak at
1948) and the un-iodinated,
abnormal
(peak at 276 W, since the abnormal tyroeines
be protonated
at these PIXIE).
Two peaks were observed,
mg and one between X0 w and 311 m&. The former un-iotinated
tyrosyl
C) and the latter 4 in derivative
to dilodotyroayl
curves for tyrosyl peak will
groups (3 In derivative
C).
A,and
In derivative
2
group8 (3 In derivative
It can be shown, by addition and dliodotyroayl
sorption
ape&rum.
one at 287
is due to the
groups,
that the tyroeyl
16 can also be concluded
curves that monolodotyroaine
A and
of separate
appear at 287 w because of the contribution
dliodotyrosyl
would still
from the
from these ab-
la absent.
CONCLUSIONS 1.
Two tyroayl
conditions
groups of rlbonuclease
used here (derivatives
iodlnated
tyrosyl
are not lodlnated
B and C).
one of the abnormal tyroeyl
(derivatives
B and C), but at a slower rate.
glnce derivatives
pounds have un-iodinated ference Ionize
spectrum must arise irreversibly
spectrum,
abnormal tyrosyl
ribonuclease
and since all groups,
from two of the tyrosyl
at alkaline
A).
groups can be iodlnated
A, B, and C, and native
the same low pH U.V. difference
the
rapidly
groups are the three normal ones (derivative
In addition,
2.
The three
under
have these com-
the low pH dlfgroups which
pH.
3. Since one of the abnormal tyrosyl groups can be iodlnated without changing the environment of the other two abnormal tyrosyl groups,
the lodinated
one, but with high pK.
abnormal group may be a reversibly Presumably, 69
it
ionizable
cannot be dletlngulshed
Vol. 5, No. 1,196l
BIOCHEMICAL
from the two other
abnormal groups In an alkaline
native
molecule
because of the irreversible
mation of the native
molecule
to conclude that this tyrosyls,
Is not near a carboxyl
titrates
possible tyrosyl 4.
unlike
like
titration
of the
change in the confor-
at high pH.
tyrosyl,
to the U.V. difference it
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
It Is also reasonable
the other
group since it
two abnormal doee not contribute
spectnun at low PH. When It is iodlnated
the three
other dliodotyrosyls,
small conformational
suggesting
change in the vicinity
a
of this
upon lodlnatlon.
The conformations
molecule
of derivatives
appear to be slmllar
Enzymat$c hydrolysis the 3 and 2 un-lodlnated, between dllodotyroslne Similar
methylated
rlbonuclease
experiments
have abnormal tyrosyls. are In progress
abnormal tyrosyl
experiments
if
the distinction
any of the latter
are being carried
(Broomfleld
to locate
groups of derivatives
should permit
and monoiodotyroslne,
fy the abnormal carboxyl abnormal tyrosyl
since all
Such studies
A and B, respectively. Is present.
A, B, C and the native
and Scheraga,
groups which are Interacting
out with 1961) to ldentiwith the
groups. REFERENCES
Broomfield,
C. A., and Scheraga, H. A., Unpublished work (1961). Gruen, L., Laskowski, Jr. M. and Scheraga, Ii. A., J. Blol. Chem. e, 2050 (1959).
Hermans, J., Jr. (1961)
and Scheraga, H. A., J. Am. Chem. Sot.,
In press
l
R. M., J. Gen. Physlol., 2, 19 (1948). Him, C. H. W. Moore, S. and Stein, W. H., J. Blol. Chem., a, 633 (ld. HugheTig$)". Jr., and Straessle, R., J. Am. Chem. Sot., 72, 452
Herrlott,
Shugar, D., Blochem. J., 52, 142 (1952). Tanford, II,
C., Hauensteln, 6409 (19%) .
J. D. and Ftands, D. G,, J. Am. Chem. Sot., 70
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
DIFFERENTIATION OF THE TYROSYLGROUPSOF RIBONUCLEASEA BY IODINATION* Chul-Yung
Cha and Harold A. Scheraga
Department of Chemistry, Received April
Cornell
Ithaca,
N. Y.
19, 1961
Three of the six tyrosyl normal (Shugar, sequence of this offers
University,
residues
1952; Tanford protein
the possibility
of rlbonuclease
et al, 1955).
IS known (Hlrs of locating
normal groups in the polypeptlde matlon about the conformation
Since the amino acid
et al, l%O),
the positions chain,
are ab-
thereby
of the molecule
iodination
of the three providing
ab-
lnfor-
In solution.
EXPERIMENTAL Rlbonuclease the recommendations lodotyrosyl Several
A was lodinated
of Hughes and Straessle
groups without
derivatives
at 10°C at pH 9.4 according
affecting
were prepared
other
to
(1950) to produce diamino acid residues.
with different
degrees of lodl-
nation.++ RESULTS Alkaline carried
Titration
Data:-
out at alkaline
Spectrophotometric
titrations
were
pH at 312 w and 295 ml.l (1O'C) to deter-
mine the number of dllodotyrosyl
and tyrosyl
residues
(Tgble
I).
*This work was supported by research grant No. E-1473 from the National Institute of Allergy and Infectious Diseases of the National Institutes of Health, Public Health Service, and by grant No. G-14792 from the National Science Foundation. **The tyrosyl groups react with iodine at different rates; three groups react rapidly and the remaining ones more slowly. For example, three groups reacted completely In 1.5 hrs. The fourth group was not completely lodinated after 3 hrs. When an amount of Iodine equivalent to six tyrosyl groups was added, two groutis remained un-lodinated even after 25 hrs., the iodine color persisting for this length of time. 67
Vol. 5, No. 1,1961
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
TABLE I TITRATION OF DIIODOTYROSYL GROUPS Number of tyrosyl groups equivalent to the amount of iodine added
Derlvatlve A
Change in molar extin;tiz ;;;ff$clent,
Number of tyrosyls
iodlnated*
,
pK*+
15,000
3.1
8.0
B
3 4
18,000
3.8
7.8
C
6
18,800
3.9
7.6
*Based on a value of 4800 er single group of dilodotyroslne in insulin (Qruen et al, 1959P . **The observed pK1s are somewhat higher than that of dilodotyrosine, 6.5, (Qruen et al, 1959) and close to that of monoiodotyrosine, 8.2, (Herrlott, 1948). However, the appearance of the U.V. absorption The high pK1s spectrum indicates that monolodotyroslne is absent. may be due to local Interactions in the lodlnated protein. The titration
at 295 R&Lshowed an increase
3000 between pH 8 and 12.5 In derivatives this
contrlbutlon
of the un-iodinated
At pH 12 and
the abnormal tyrosyl
on standing Is similar
12.5
at room temperature to that of native
U.V. Difference obtained
A, B, and C.
is due to the dilodotyrosyl
to the Ionization
for
in E of about groups rather
abnormal tyrosyl groups ionize
several
groups. Irreversibly
hours.
This behavior
U.V. difference
spectra were
at low pH and compared with those for native 1961).
than
rlbonuclease.
Spectra at Low pH:-
(Hermans and Scheraga,
However,
The difference
spectra
ribonuclease of deriva-
tives A, B, C are similar to each other and to that of the unlodlnated molecule. Since the native protein contains two tyrosylcarboxyl
hydrogen bonds imbedded In hydrophobic
and Scheraga, exist In all
1961),
In derivatives 3 derivatives;
regions
it appears that these interactions A, B, and C. it
Precipitation
seems that the solubillty
Is decreased at low pH by lodinatlon. 68
(Hermans still
occurs below pH 1 of ribonuclease
BIOCHEMICAL
Vol. 5, No. 1,196l
U.V. Absorption tives
Spectra:-
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
The U.V. abeorption
spectra
of deriva-
A and C were examined between 270 w and 3aO w at pH 10.5
and 11.5, respectively, 305 w according tyrosinee
to search, for monolodotyrosine
to Herrlott,
(peak at
1948) and the un-iodinated,
abnormal
(peak at 276 W, since the abnormal tyroeines
be protonated
at these PIXIE).
Two peaks were observed,
mg and one between X0 w and 311 m&. The former un-iotinated
tyrosyl
C) and the latter 4 in derivative
to dilodotyroayl
curves for tyrosyl peak will
groups (3 In derivative
C).
A,and
In derivative
2
group8 (3 In derivative
It can be shown, by addition and dliodotyroayl
sorption
ape&rum.
one at 287
is due to the
groups,
that the tyroeyl
16 can also be concluded
curves that monolodotyroaine
A and
of separate
appear at 287 w because of the contribution
dliodotyrosyl
would still
from the
from these ab-
la absent.
CONCLUSIONS 1.
Two tyroayl
conditions
groups of rlbonuclease
used here (derivatives
iodlnated
tyrosyl
are not lodlnated
B and C).
one of the abnormal tyroeyl
(derivatives
B and C), but at a slower rate.
glnce derivatives
pounds have un-iodinated ference Ionize
spectrum must arise irreversibly
spectrum,
abnormal tyrosyl
ribonuclease
and since all groups,
from two of the tyrosyl
at alkaline
A).
groups can be iodlnated
A, B, and C, and native
the same low pH U.V. difference
the
rapidly
groups are the three normal ones (derivative
In addition,
2.
The three
under
have these com-
the low pH dlfgroups which
pH.
3. Since one of the abnormal tyrosyl groups can be iodlnated without changing the environment of the other two abnormal tyrosyl groups,
the lodinated
one, but with high pK.
abnormal group may be a reversibly Presumably, 69
it
ionizable
cannot be dletlngulshed
Vol. 5, No. 1,196l
BIOCHEMICAL
from the two other
abnormal groups In an alkaline
native
molecule
because of the irreversible
mation of the native
molecule
to conclude that this tyrosyls,
Is not near a carboxyl
titrates
possible tyrosyl 4.
unlike
like
titration
of the
change in the confor-
at high pH.
tyrosyl,
to the U.V. difference it
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
It Is also reasonable
the other
group since it
two abnormal doee not contribute
spectnun at low PH. When It is iodlnated
the three
other dliodotyrosyls,
small conformational
suggesting
change in the vicinity
a
of this
upon lodlnatlon.
The conformations
molecule
of derivatives
appear to be slmllar
Enzymat$c hydrolysis the 3 and 2 un-lodlnated, between dllodotyroslne Similar
methylated
rlbonuclease
experiments
have abnormal tyrosyls. are In progress
abnormal tyrosyl
experiments
if
the distinction
any of the latter
are being carried
(Broomfleld
to locate
groups of derivatives
should permit
and monoiodotyroslne,
fy the abnormal carboxyl abnormal tyrosyl
since all
Such studies
A and B, respectively. Is present.
A, B, C and the native
and Scheraga,
groups which are Interacting
out with 1961) to ldentiwith the
groups. REFERENCES
Broomfield,
C. A., and Scheraga, H. A., Unpublished work (1961). Gruen, L., Laskowski, Jr. M. and Scheraga, Ii. A., J. Blol. Chem. e, 2050 (1959).
Hermans, J., Jr. (1961)
and Scheraga, H. A., J. Am. Chem. Sot.,
In press
l
R. M., J. Gen. Physlol., 2, 19 (1948). Him, C. H. W. Moore, S. and Stein, W. H., J. Blol. Chem., a, 633 (ld. HugheTig$)". Jr., and Straessle, R., J. Am. Chem. Sot., 72, 452
Herrlott,
Shugar, D., Blochem. J., 52, 142 (1952). Tanford, II,
C., Hauensteln, 6409 (19%) .
J. D. and Ftands, D. G,, J. Am. Chem. Sot., 70