- Email: [email protected]
Conformational differences between s-RNA and aminoacyl s-RNA
Vol. 20, No. 4, 1965
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
CONFORMATIONAL DIFFERENCES BETWEEN s-RNA ANDAMINOACYLs-RNA P. S. Serin and P. C. Zamecnik The John Collins Warren laboratories of the Huntington Memorial Hospital of Barvard University at the Massachusetts General Hospital, Boston, Mass.
ReceivedJune 22, 1965 Current interest been directed
in the mechanismof protein
biosynthesis has
to the study of the role of a-RNA,* m-RNAand ribosomes
in the biosynthetic
process.
According to present concepts, aminoacyl
s-RNA binds to the messenger-polysome complex, and after its amino acid to the growing polypeptide template.
To satisfy
transferring
chain, dissociates from the
the requirement of the binding of the anticodon
on S-RNA to the codon on the template, a conformation dependent parameter may be involved.
To search for a possible conformational
ence between s-R&! and aminoacyl S-RNA, the technique of optical
differrotatory
dispersion has now been employed. Optical
rotatory
dispersion measurementshave been widely used
in the past for the study of the helix-coil and proteins
transition
in polypeptides
(Urnes and Doty, 19611, and have been extended recently
to the study of polynucleotides and Tinoco, 1965; Lamborg-et al.,
and s-RNA (Fasmane al., 1965).
In an earlier
1964; Holcomb publication
(Sarin and Zamecnik, 1965), we reported on the application the study of
StNCtUrd
acceptor and transfer
of ORDto
patterns of the components of the amino acid systems. We now wish to report a conformational
-k Abbreviations: Tris, tris(hydroxymethyl)aminomethane; aminoacyl s-RNA, s-RNA charged with 21 amino acids; S-RNA, this polynucleotide stripped of all amino acids? m-RNA, messenger RNA; A, adenine: C, Cytosine; G, guanine; 0, uracil; and ORD, optical rotatory dispersion.
400
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 20, No. 4,1965
difference
between
mined whether binding
such may be related
to the m-RNA-ribosome
unesterified
stripped
amino acids
mixture
4 vols.
was cooled
of absolute
was dialysed
ing of s-RNA. material (Scott,
incubation, with
0.1 M sodium chloride
with
was repeated
respect
reported
and aminoacyl
(3:1,
was well
for 2 hrs.
dispersion
(Lamborg et al.,
s-RNA were
until
determined
of protein
v/v)
shaken,
2 ~01s.
and the
The extraction there
to sodium chloride
was no prethe aminoacyl
and dialyzed
and finally
The dialyzed
and the sample was checked for rotatory
and Zamecnik,
a-EUVAwas freed alcohol
The mixture
a Gary 60 spectropolarimeter
already
(Sarin
follow-
(r4C Phe) was added to check the label-
in the cold overnight.
Optical
Water
lyophi-
21 amino acids,
The aqueous phase containing
(aqueous)
extrac-
water.
and finally
reported
chloroform:isoamyl
alcohol
s-RNA was made 0.1 M with
lyophilysed,
by adding
changes the sample
was removed by centrifugation.
at the interface.
water
for 48 hrs.
the
dissolved
distilled
three
the aminoacyl
procedure).
chloroform:isoamyl
distilled
the first
water
C amino acid
precipitate
cipitate
and after
against
to the ones already
by extraction
separated with
14
unpublished
incubation,
Tris was removed by this
s-RNA was then charged with
After
After
1964).
of Tris-
and s-RNA was precipitated
The excess
distilled
similar
One marker
Ohio) was
at 37 ' in the presence
and dialyzed
2 hre.,
against
ing conditions
Falls,
s-RNA was removed by centrifugation,
The stripped
1965).
degree of
s-RNA compared to
Chagrin
and Zamecnik, in ice,
in a small volume of water, was changed every
Biochemicals,
ethanol.
The precipitated
lyzed.
to be deter-
greater
of aminoacyl
by incubation
(1.8 M, pH 8) (Sarin
reaction
It remains
to the apparently
complex,
s-RNA (General
of all
acetate
s-RNA.
s-RNA.
E. coli
tion.
s-RNA and aminoacyl
dialyzed
against against
sample was then
the absence of ATP.
was measured from 320 mp to 230 mp using 1965).
conditions
similar
08D measurements
at a concentration
401
to the ones of s-RNA
of 0.4 mg/ml
Vol. 20, No. 4, 1965
BIOCHEMICAL AND BlOPHYSlCAL RESEARCH COMMUNICATlONS
in 0.2 M sodium was determined
citrate by inorganic
s-RNA and aminoacyl in order
buffer
to gain
stabilities
(pH 7).
phosphate
s-RNA were insight
Concentration
into
to protonating
also the
of a-RNA samples
estimation. carried
OlUJ measurements
out as a function
similarity
of
of pH,
or differences
in their
environments.
-41 220
240
260
260
300
320
WA YEa! ENGTH, tq~
Fig. 1. Optical rotatory buffer. pH 7, (0 -0)~ (X -8); pH 3, (U--a>.
citrate 3.5,
As can be seen fran Cotton
effects
is observed
90% of the amplitude of the from
ordered
but
No change
on lowering
due to the protonation
the Cotton
effects
amplitude tude
becomes
concomitant relatively changed
from
3.5
change,
about
to 3.
disruption
the pH ie- changed occurs,
The amplitude
of
at pH 7.
Further
a considerable
change,
and the
at pH 7.
change
in ampli-
‘Ibis
of the A residues bon&d
57% to 49%, is
with
structures.
observed
Thue at pH 3 when most of the
402
of
to be
disruption
of the amplitude
of the A-U hydrogen from
when
amplitude
is found
a partial
of the C residues.
due to the protonation
disruption small
thereby
the pH to 4 a further
57% of the amplitude
ia presumably
in the
amplitude
is observed
at pH 4 ia 84% that
of the pH to 3.5 brings
s-RNA in 0.2 M aodium pH 4, (r--q>; pH
change
at pH 5, when the
presumably
lowering
1 the first
at pH 7, suggesting
structure.
5 to 4.5,
Fig.
dispersion of pH 5, (O---O);
when the
a Only a pH is
C and A residues
BIOCHEMICAL AND BlOWlYSiCAL RESEARCH COMMUNICATIONS
Vol. 20, No. 4,1965
would have been protonated,
the amplitude
found to be SD% of the amplitude to longer wavelength the pH is lowered that
this
from 4 to 3 through
structures
suggesting
which
seem to shield
regions
hydrogen
likely
in strong
to be disrupted
suggest rather
that
This suggestion alanine
agrees with
s-RNA by Holley
2.
in the secondary
82% of that lowering
of s-RNA.
is also
decrease
observed,
nitrogenous
cific
bonded helical
to
regions structure.
determination
of
(aminoacyl
seems to occur, effects
of aminoacyl
A large decrease
with
with
again suggesting
s-RNA is respect
in amplitude
to the change observed
in amplitude
with
of differently
to
occurs s-RNA.
change in pH of aminoacyl
the presence
an
as shown in Fig.
change in amplitude
is parallel
s-RNA),
s-RNA
shielded
bases.
In order ference
ordered
structural
of Cotton
at pH 4.5.
at pH 3.5 and 3, which
are
seems plausible
21 amino acids
A noticeable
of pH occurs
A non-linear
Thus it
which
(1965).
structure
Thus at pH 7 the amplitude
The non-linearity
bonded regions
hydrogen
When s-RNA is charged with alteration
of the bases
could also be due to the engulf-
the primary
--et al.
ordered
of the nitrogenous
is composed of short,
completely
in pH
of different
bonded environments.
only at low pH.
than a single,
lowering
of the bases in hydrophobic
GC hydrogen
s-RNA structure
to note
The inaccessibility
in the opening of the s-RNA structure ing of some bases
with
the availability
environments.
occura when
is of interest
of regions
may be due to the burying
or in strongly
It
is
a marked shift
point
structure
the presence
baaea to the protonating to protonation
3.5.
of the secondary
effects
In addition,
at pH 7.
of the peak and the crosswer
disruption
is non-linear,
of the Cotton
to answer
in amplitude absorption
the question
might be simply
as to whether
a reflection
at 260 mt~, a sample of aminoacyl
at 37O in the presence
of Tria-acetate 403
(2 M, pH 8).
the observed
dif-
of a change in apeS-RNA was incubated Fifty
~1 aliquota
Vol. 20, No. 4,1965
BIOCHEMICAL AND BIOPHYSKAL RESEARCH COMMUNICATIONS
+4
“:
t2
9 z 0 2 4. -2
-4 220
240 260 WA YEL ENGUf,
280 m/
300
320
Fig. 2. Optical rotatory dispersion of aminoacyl M sodium citrate buffer. pH 4.5, (o---O>; pH 7, (0 -0); (V-r>; pH 3.5, (X-X); pH 3, (CI--0).
containing
40-50 ng s-RNA were
to 1 ml with
shift
ultraviolet
the radioactivity Both types
spectrophotometer.
was observed due to
over a period 14
of the aminoacyl
alcohol s-RNA.
at 260 mp was then
of 90 min.
during
and dialysis
The difference8
and the pH readjusted It becomes apparent
charged with
21 amino acids
compared to s-RNA strfpped conformation binding
of aminoacpl
of aminoacyl
this
All period.
of incubation,
during
preparation
in the ORD of aminoacyl
and s-RNA were also found when a sample of aminoacyl dialyzed
hypo-
incubation.
to the same procedure
extraction,
and diluted
no detectable
C amino acid was lost
of sample were subjected
chlorofozm:isoamyl
intervals
The absorbance
0.14 M sodium chloride.
read in a Zeiss chromic
removed at 10 min.
s-RNA in 0.2 pH 4,
a-RNA
s-RNA was stripped,
to pH 7. from the above observation6 has a different
of all
conformation
amino acids.
s-RN4 may be important
e-RNA to the template
404
that (less
s-RNA helical)
This difference
in the
in the preferential
in protein
biosynthesis.
Vol. 20, No. 4, 1965
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Acknowledgments The authors are helpful criticism. This Cancer Society (II-102G) AT(30-11-2643). This is of Harvard University.
indebted to Dra. J. F. Scott and M. Lamborg for work was supported by grants from the American and the Atomic Rnergy Commission (Contract No. publication Wo. 1213 of the Cancer Commission
References Fasman, G. D., Lindblow, C., and Groasman, L., Biochemistry, 3, 1015 (1964) Holcomb, D. N., and Tfnoco, I., Biopolymere, 2, 121 (19653 Holley, R. W., Apgar, J., Everett, G. A., Madison, J, T., Marquisee, M., Merrill, S. H., Penwick, J. R,, and Zamir, A., Science, 147, 1462 (1965) Lamborg, M. R., Zamecnik, P. C., Li, T. K., Kagi, J., and Vallee, B. L., Biochemistry, 2, 63 (1965) Sarin, P. S., and Zamecnik, P. C., Biochfm. Biophya, Acta, 9l, 653 (1964) Sarin, P. S., and Zamecnik, P. C., Biochem. Biophys. Res. Conmt., l9* 198 (1965 > Urnes, P., and Doty, P,, Adv. Protein Chest., l6, 401 (1961)
405
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
CONFORMATIONAL DIFFERENCES BETWEEN s-RNA ANDAMINOACYLs-RNA P. S. Serin and P. C. Zamecnik The John Collins Warren laboratories of the Huntington Memorial Hospital of Barvard University at the Massachusetts General Hospital, Boston, Mass.
ReceivedJune 22, 1965 Current interest been directed
in the mechanismof protein
biosynthesis has
to the study of the role of a-RNA,* m-RNAand ribosomes
in the biosynthetic
process.
According to present concepts, aminoacyl
s-RNA binds to the messenger-polysome complex, and after its amino acid to the growing polypeptide template.
To satisfy
transferring
chain, dissociates from the
the requirement of the binding of the anticodon
on S-RNA to the codon on the template, a conformation dependent parameter may be involved.
To search for a possible conformational
ence between s-R&! and aminoacyl S-RNA, the technique of optical
differrotatory
dispersion has now been employed. Optical
rotatory
dispersion measurementshave been widely used
in the past for the study of the helix-coil and proteins
transition
in polypeptides
(Urnes and Doty, 19611, and have been extended recently
to the study of polynucleotides and Tinoco, 1965; Lamborg-et al.,
and s-RNA (Fasmane al., 1965).
In an earlier
1964; Holcomb publication
(Sarin and Zamecnik, 1965), we reported on the application the study of
StNCtUrd
acceptor and transfer
of ORDto
patterns of the components of the amino acid systems. We now wish to report a conformational
-k Abbreviations: Tris, tris(hydroxymethyl)aminomethane; aminoacyl s-RNA, s-RNA charged with 21 amino acids; S-RNA, this polynucleotide stripped of all amino acids? m-RNA, messenger RNA; A, adenine: C, Cytosine; G, guanine; 0, uracil; and ORD, optical rotatory dispersion.
400
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 20, No. 4,1965
difference
between
mined whether binding
such may be related
to the m-RNA-ribosome
unesterified
stripped
amino acids
mixture
4 vols.
was cooled
of absolute
was dialysed
ing of s-RNA. material (Scott,
incubation, with
0.1 M sodium chloride
with
was repeated
respect
reported
and aminoacyl
(3:1,
was well
for 2 hrs.
dispersion
(Lamborg et al.,
s-RNA were
until
determined
of protein
v/v)
shaken,
2 ~01s.
and the
The extraction there
to sodium chloride
was no prethe aminoacyl
and dialyzed
and finally
The dialyzed
and the sample was checked for rotatory
and Zamecnik,
a-EUVAwas freed alcohol
The mixture
a Gary 60 spectropolarimeter
already
(Sarin
follow-
(r4C Phe) was added to check the label-
in the cold overnight.
Optical
Water
lyophi-
21 amino acids,
The aqueous phase containing
(aqueous)
extrac-
water.
and finally
reported
chloroform:isoamyl
alcohol
s-RNA was made 0.1 M with
lyophilysed,
by adding
changes the sample
was removed by centrifugation.
at the interface.
water
for 48 hrs.
the
dissolved
distilled
three
the aminoacyl
procedure).
chloroform:isoamyl
distilled
the first
water
C amino acid
precipitate
cipitate
and after
against
to the ones already
by extraction
separated with
14
unpublished
incubation,
Tris was removed by this
s-RNA was then charged with
After
After
1964).
of Tris-
and s-RNA was precipitated
The excess
distilled
similar
One marker
Ohio) was
at 37 ' in the presence
and dialyzed
2 hre.,
against
ing conditions
Falls,
s-RNA was removed by centrifugation,
The stripped
1965).
degree of
s-RNA compared to
Chagrin
and Zamecnik, in ice,
in a small volume of water, was changed every
Biochemicals,
ethanol.
The precipitated
lyzed.
to be deter-
greater
of aminoacyl
by incubation
(1.8 M, pH 8) (Sarin
reaction
It remains
to the apparently
complex,
s-RNA (General
of all
acetate
s-RNA.
s-RNA.
E. coli
tion.
s-RNA and aminoacyl
dialyzed
against against
sample was then
the absence of ATP.
was measured from 320 mp to 230 mp using 1965).
conditions
similar
08D measurements
at a concentration
401
to the ones of s-RNA
of 0.4 mg/ml
Vol. 20, No. 4, 1965
BIOCHEMICAL AND BlOPHYSlCAL RESEARCH COMMUNICATlONS
in 0.2 M sodium was determined
citrate by inorganic
s-RNA and aminoacyl in order
buffer
to gain
stabilities
(pH 7).
phosphate
s-RNA were insight
Concentration
into
to protonating
also the
of a-RNA samples
estimation. carried
OlUJ measurements
out as a function
similarity
of
of pH,
or differences
in their
environments.
-41 220
240
260
260
300
320
WA YEa! ENGTH, tq~
Fig. 1. Optical rotatory buffer. pH 7, (0 -0)~ (X -8); pH 3, (U--a>.
citrate 3.5,
As can be seen fran Cotton
effects
is observed
90% of the amplitude of the from
ordered
but
No change
on lowering
due to the protonation
the Cotton
effects
amplitude tude
becomes
concomitant relatively changed
from
3.5
change,
about
to 3.
disruption
the pH ie- changed occurs,
The amplitude
of
at pH 7.
Further
a considerable
change,
and the
at pH 7.
change
in ampli-
‘Ibis
of the A residues bon&d
57% to 49%, is
with
structures.
observed
Thue at pH 3 when most of the
402
of
to be
disruption
of the amplitude
of the A-U hydrogen from
when
amplitude
is found
a partial
of the C residues.
due to the protonation
disruption small
thereby
the pH to 4 a further
57% of the amplitude
ia presumably
in the
amplitude
is observed
at pH 4 ia 84% that
of the pH to 3.5 brings
s-RNA in 0.2 M aodium pH 4, (r--q>; pH
change
at pH 5, when the
presumably
lowering
1 the first
at pH 7, suggesting
structure.
5 to 4.5,
Fig.
dispersion of pH 5, (O---O);
when the
a Only a pH is
C and A residues
BIOCHEMICAL AND BlOWlYSiCAL RESEARCH COMMUNICATIONS
Vol. 20, No. 4,1965
would have been protonated,
the amplitude
found to be SD% of the amplitude to longer wavelength the pH is lowered that
this
from 4 to 3 through
structures
suggesting
which
seem to shield
regions
hydrogen
likely
in strong
to be disrupted
suggest rather
that
This suggestion alanine
agrees with
s-RNA by Holley
2.
in the secondary
82% of that lowering
of s-RNA.
is also
decrease
observed,
nitrogenous
cific
bonded helical
to
regions structure.
determination
of
(aminoacyl
seems to occur, effects
of aminoacyl
A large decrease
with
with
again suggesting
s-RNA is respect
in amplitude
to the change observed
in amplitude
with
of differently
to
occurs s-RNA.
change in pH of aminoacyl
the presence
an
as shown in Fig.
change in amplitude
is parallel
s-RNA),
s-RNA
shielded
bases.
In order ference
ordered
structural
of Cotton
at pH 4.5.
at pH 3.5 and 3, which
are
seems plausible
21 amino acids
A noticeable
of pH occurs
A non-linear
Thus it
which
(1965).
structure
Thus at pH 7 the amplitude
The non-linearity
bonded regions
hydrogen
When s-RNA is charged with alteration
of the bases
could also be due to the engulf-
the primary
--et al.
ordered
of the nitrogenous
is composed of short,
completely
in pH
of different
bonded environments.
only at low pH.
than a single,
lowering
of the bases in hydrophobic
GC hydrogen
s-RNA structure
to note
The inaccessibility
in the opening of the s-RNA structure ing of some bases
with
the availability
environments.
occura when
is of interest
of regions
may be due to the burying
or in strongly
It
is
a marked shift
point
structure
the presence
baaea to the protonating to protonation
3.5.
of the secondary
effects
In addition,
at pH 7.
of the peak and the crosswer
disruption
is non-linear,
of the Cotton
to answer
in amplitude absorption
the question
might be simply
as to whether
a reflection
at 260 mt~, a sample of aminoacyl
at 37O in the presence
of Tria-acetate 403
(2 M, pH 8).
the observed
dif-
of a change in apeS-RNA was incubated Fifty
~1 aliquota
Vol. 20, No. 4,1965
BIOCHEMICAL AND BIOPHYSKAL RESEARCH COMMUNICATIONS
+4
“:
t2
9 z 0 2 4. -2
-4 220
240 260 WA YEL ENGUf,
280 m/
300
320
Fig. 2. Optical rotatory dispersion of aminoacyl M sodium citrate buffer. pH 4.5, (o---O>; pH 7, (0 -0); (V-r>; pH 3.5, (X-X); pH 3, (CI--0).
containing
40-50 ng s-RNA were
to 1 ml with
shift
ultraviolet
the radioactivity Both types
spectrophotometer.
was observed due to
over a period 14
of the aminoacyl
alcohol s-RNA.
at 260 mp was then
of 90 min.
during
and dialysis
The difference8
and the pH readjusted It becomes apparent
charged with
21 amino acids
compared to s-RNA strfpped conformation binding
of aminoacpl
of aminoacyl
this
All period.
of incubation,
during
preparation
in the ORD of aminoacyl
and s-RNA were also found when a sample of aminoacyl dialyzed
hypo-
incubation.
to the same procedure
extraction,
and diluted
no detectable
C amino acid was lost
of sample were subjected
chlorofozm:isoamyl
intervals
The absorbance
0.14 M sodium chloride.
read in a Zeiss chromic
removed at 10 min.
s-RNA in 0.2 pH 4,
a-RNA
s-RNA was stripped,
to pH 7. from the above observation6 has a different
of all
conformation
amino acids.
s-RN4 may be important
e-RNA to the template
404
that (less
s-RNA helical)
This difference
in the
in the preferential
in protein
biosynthesis.
Vol. 20, No. 4, 1965
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Acknowledgments The authors are helpful criticism. This Cancer Society (II-102G) AT(30-11-2643). This is of Harvard University.
indebted to Dra. J. F. Scott and M. Lamborg for work was supported by grants from the American and the Atomic Rnergy Commission (Contract No. publication Wo. 1213 of the Cancer Commission
References Fasman, G. D., Lindblow, C., and Groasman, L., Biochemistry, 3, 1015 (1964) Holcomb, D. N., and Tfnoco, I., Biopolymere, 2, 121 (19653 Holley, R. W., Apgar, J., Everett, G. A., Madison, J, T., Marquisee, M., Merrill, S. H., Penwick, J. R,, and Zamir, A., Science, 147, 1462 (1965) Lamborg, M. R., Zamecnik, P. C., Li, T. K., Kagi, J., and Vallee, B. L., Biochemistry, 2, 63 (1965) Sarin, P. S., and Zamecnik, P. C., Biochfm. Biophya, Acta, 9l, 653 (1964) Sarin, P. S., and Zamecnik, P. C., Biochem. Biophys. Res. Conmt., l9* 198 (1965 > Urnes, P., and Doty, P,, Adv. Protein Chest., l6, 401 (1961)
405