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Affinity chromatography of aminoacyl-tRNA synthetases on specific tRNA columns without prior purification of tRNA
Vol. 60, No. 4, 1974
BIOCHEMICAL
AFFINITY CHROMATOGRAPHY SPECIFIC tRNA COLUMNS Catherine
September
RESEARCH COMMUNICATIONS
OF AMINOACYL-tRNA SYNTHETASES ON WITHOUT PRIOR PURIFICATION OF tRNA
M. Joyce and Jeremy
The Dyson Perrins Laboratory,
Received
AND BIOPHYSICAL
University
R. Knowles*
of Oxford,
Oxford
OX1 3QY,
U.K.
3,l.974
SUMMARY. A method is described for the purification of aminoacyl-tRNA synthetases by chromatography, using a column of tRNA lacking the cognate tRNA, followed by a column of the cognate tRNA. The ability of the enzyme to discriminate between cognate and non-cognate tRNA is exploited in a novel and rapid preparation of the two columns. The purification graphic
techniques
enzymes
is usually
tiresome,
in crude cell extracts.
particularly
helpful
So far, affinity natural
of aminoacyl-tRNA
synthetases largely
In such a situation
for synthetase
amino acids (l-3)
and tRNA
tRNA have proved
more satisfactory.
However
column
of pure tRNA cognate purification
have pointed
out that such methods are unable
recognises
general
features
affinity
columns:
lacking
the cognate
Y
Copyright All rights
0 1974
features
of all tRNA’s.
Present address:
Abbreviations:
one might expect
specific
a column tRNA,
(4-8);
of a single
to separate tRNA,
this latter
made use of a
(4,5,7)
did not achieve
Ebel and coworkers
the desired
a method
preceded
Harvard
University,
recognising
involving
two of tRNA
proteins.
Cambridge,
Phe-RS, phenylalan I-tRNA synthetase; similarly for other see Scheme. synthetases. tRNA &al , tRNAox, tRNAoxmed:
1278
(6)
synthetase,
by a column
to remove other tRNA-binding
Department of Chemistry, Mass.02138.
the use of the
from other enzymes
proposed
tRNA,
time.
of these the methods involving
those methods which
They therefore
should be
in a shorter
have involved
from this technique.
of pure cognate
by Academic Press, Inc. in any form reserved.
of reproduction
isolation
of these
chromatography
with the target enzyme
the dramatic
which
affinity
factors may be obtained
substrates,
single
chromato-
due to the low concentration
since larger purification
methods reported
by conventional
In this
Vol. 60, No. 4, 1974
BIOCHEMICAL
way yeast Phe-RS
was purified
Ser-RS to 8590%
purity
of the necessary
from non-cognate
this very distinction with tRNA; avoiding
to homogeneity
tRNA.
(between
it is possible
a laborious
(6) and more recently
A particular
cognate
to exploit
fractionation
pair of columns
requires
and non-cognate
the desired
of tRNA by physical
techniques.
the actual
sequence
achieving
in this way a considerable
advantage
of this system is that a pure enzyme preparation
specificity
can be achieved
synthetases
and crude
of reactions
cognate
tRNA,
susceptible
to oxidative
may be coupled separation
tRNA.
affinity
cleavage
so a borohydride
in subsequent
the cognate
tRNA susceptible,
thus providing
reactions.)
to differentiate
precedent;
several
(see e.g.:
11,12).
tRNA,
reduction
of crude
The resulting
of the and dialdehyde
48, thus achieving
both the
of one of the non-cognate out to prevent
of the aminoacyl
tRNA its
group leaves
and coupling
to the carrier
column.
aminoacylation
between
(9).
of the oxidised
to oxidation
since total
remains intact
(10) is carried
Hydrolysis
in its turn,
A further
out using unfractionated
and the production
removal
the second affinity
The use of the enzymic oxidation
of Sepharose
(In practice,
participation
matrix,
by sodium periodate
material,
at the 3’-terminus
tRNA this feature
from non-cognate
to the column
amino acid to a mixture
masks the -cis-glycol
derivative
tRNA during
is not required
is carried
thus
We have used
in both time and effort.
a single
in the non-cognate
separation,
and non-cognate
is coupled
When the reaction
columns.
may not be complete,
cognate
tRNA
saving
by adding
ta a hydrazide
of cognate
necessary
in which
temporarily
while
between
makes
in its interaction
this fact to effect
to discriminate
the separation
synthetase
species)
reaction
aminoacylation
rat liver
solely
aminoacyl-tRNA
the enzyme
tRNA,
RESEARCH COMMUNICATIONS
(8).
The preparation of cognate
AND BIOPHYSICAL
cognate
reaction
in conjunction
and non-cognate
methods for the purification
1279
tRNA
with periodate
is not without
of tRNA are based on this principle
Vol.
60,
No.
4, 1974
BIOCHEMICAL
AND
Mixed
a:
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
tRNA
charging
+RNA””
tRNA-Va’
b OA
(all
(Val-tRNAva’) Hd
6-Val
HO
b:
OH
oxidation
1
tRNAVa’ M
tRNA-“*’
+ HO
(tRNA-Val) ox
O-V&l
c:
tRNAVa’
coup1
ing
-
I
+
+ any HO
other
uncoupled
tRNAox
-Val
O-&II
$
separation
of
Sepharose I
e:
reduction
tRNA-Val
tRNAVa’
+ HO
(tRNA;;f;ed) HO
O-&l
OH
I
Scheme.
f:
discharging
g:
oxidation
Preparation
of and
of affinity
Val-tRNAVa’ coupling
and
1280
of tRNAVa’
anti-affinity
columns
tRNAs)
BIOCHEMICAL
Vol. 60, No. 4,1974
RESULTS AND
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
DISCUSSION
tRNA columns designed
for the purification
of Val-RS
were prepared
as shown
in the Scheme. When an impure enzyme column, higher
the elution capacity
However,
profile
gel electrophoresis
of tRNAVa’
Improved mixture
material Val-RS
purification
was achieved on a column
and concentrated;
relative
then chromatographed
on the tRNAVat
-Val
a single
protein
proteins.
the crude enzyme sample was applied
which
frontally.
A suitable (Fig.2);
column
: the enzyme
assays showed,
column
with other synthetases.
above)
by first subjecting
to other synthetases.
the much
from other tRNA-binding
of tRNA
Val
showed three major components.
since (as mentioned Val-RS
on the tRNA
demonstrating
compared
fractions
washed to remove non-bound
was pooled activity
for Val-RS
of the pooled
of separating
to chromatography
and the column
material
to be expected
*IS incapable
was chromatographed
shown in Fig. 1 was obtained,
of this column
This result was entirely
solution
eluted
This
as expected,
an increase
quantity
of this pool was
gel electrophoresis
of the
a The aminoacylation mixture contained: 104mM-trien-HCl buffer, pH 7.2, -%g(OAc)2 (IO,4 mM), KCI (10.4 mM), ATP (2.1 m/v!), valine (0.83 mM), crude E .Coli tRNA (1.67 mg/ml) (Wh a t man Biochemicals Maidstone, Kent, U.K.), and Val-RS (100-1000 /,runits/ml). After 2 h at 4 d C, the reaction was quenched by cooling in ice and the tRNA recovered by phenol extraction followed by ethanol precipitation. b tRNA was oxidised according to Remy et al. (6). c Qxidised tRNA was coupled to the carfiatrix (6) [commercial CNBrictivated Sepharose (Pharmacia, Uppsala, Sweden) derivatised, in accordance with the manufacturers’ instructions, with adipic acid dihydrazide (13).1. d Functionalised Sepharose was recovered by filtration, washed and treated with NaBH4 (6). The tRNA-containing washings were combined and the tRNA recovered by lyophilisation for use in the following stages. e Reduction of any residual oxidised tRNA was carried out using excess NaBH4 p r&mg tRNA) in lM-phosphate buffer, pH 7, for 2 h at room temperature in the dark. f The tRNA was dialysed against 0.1 M-glycine buffer, pH 10.3, for 5 h at Gem temperature. Typically the fiq:folumn comprised 6 ml (settled bed volume) Sepharose carrying and the second column 1 ml Sepharose carrying 1 r&ml ,$$leNA ’ .
1281
in
Vol. 60, No. 4, 1974
BIOCHEMICAL
cp.m in
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
c.pm in assay
assuy
0
Figures.
Elution
profiles
of tRNA columns
(for details
see text)
All columns were run using O.OSM-acetate buffer, pH 5.5, containing glycerol (10% v/v), bCl (IOmM), EDTA (0.1 mM), and P-mercaptoethanol (20mM). The enzyme samp Pe was a partially purified mixture containing Val-, Leu-, Met-, and Tyr-tRNA synthetases from B.Stearothermophilus (kind gift of Drs. K. Sargeant and A. Atkinson, Microbiological Research Establishment, Porton Down, Salisbury, Wilts., U.K.). After extensive washing to remove non-bound protein, the bound protein was eluted with a linear gradient (at c ) of KCI (O-1M). Fractions were assayed for Val-RS ( -t ), Leu-RS (+), and Tyr-RS ( 4) as described by Wilkinson and Knowles (14): A280 (- -. - . . e). Fractions marked w were pooled and concentrated.
fractions
containing
Val-RS
In principle, general provided
should
the separation
tRNA features
we achieved
not bind - however,
ASSESSMENT
AND
now showed a single of Val-RS
can be accomplished
that one column
For example,
activity
is capable a similar
from other enzymes which using any pair of specific
of retaining
Val-RS
result using a tRNA
see below),
major component.
followed
while Leu
by a tRNA
recognise
tRNA columns,
the other is not.
column Val
(to which Val-RS
column.
SCOPE OF THE METHOD
In this paper we have described
the successful 1282
development
and application
Vol.
60,
No.
of a method chromatography drawbacks
BIOCHEMICAL
4, 1974
for
the
purification
on specific of affinity
AND
BIOPHYSKAL
of an aminoacyl tRNA
columns.
chromatography,
tRNA Our
notably
synthetase
method the
RESEARCH
time
c.p.m. in assay
avoids and
effort
COMMUNICATIONS
using one
of the
main
expended
in
c.p.m. in assay
16000 ,-
8coo
c.p.m. in assay
0
5
IO Fraction
1283
15 Number
20
25
affinity
the
Vol. 60, No. 4, 1974
preparation
BIOCHEMICAL
of the ligand
to the affinity
matrix. concurrently
preparation
barely
enzyme,
(in this case, the purified Since the separation
takes place
to be coupled
from non-cognate
tRNA
for the two coupling
reactions.
complete
of the target
described
did not effect still
being detectable
the reactions
upon which
depends
(in particular
the charging
and this results in some overlap
the separation reaction
degree
that,
purification
the entire
on gel electrophoresis. of cognate
This is
from non-cognate
tRNA
to completion,
of the two columns.
Nevertheless,
of purification
with further
column,
(15)) may not proceed
in specificity
that a very substantial
is reason to believe
of cognate
tRNA)
the time required
because
there
cognate
of the first affinity
minor contaminants
it is clear
RESEARCH COMMUNICATIONS
with the preparation
exceeds
The columns
AND BIOPHYSICAL
refinement
has been achieved, of the method,
and
this could
be
improved. Application be possible,
of this method
subject
to the following
First, the desired
problem
but unable
in attempting
both Val-RS
heterologous similar
amino
Secondly,
one from the other. of Leu-RS: with,
e.g.,
In this situation, satisfactory separation
mischarging
of co-purifying
We encountered
the tRNALeU Tyr-RS)
errors are more frequent,
for the successful
should also
tRNA;
capable
tRNA Val by B.Stearothermophilus
acids are concerned. should permit
only its cognate
a pair of columns
(compared
of E.Coli
system, charging
the same organism
*
to separate
and Leu-RS strongly
to be due to mischarging
must charge
produce
the purification
synthetases
conditions.
synthetase
of a second tRNA species would two synthetases
to other aminoacyl-tRNA
particularly
column
this
retained
(Fig.3).
This seems
Leu-RS. where
In a
chemically
use of enzyme and tRNA
application of cognate
,
from
of our method.* from non-cognate
tRNA,
Val As mentioned above, this tRNALeU column was used in conjunction with a tRNA column in the purification of Val-RS; in this case the ability of the tRNALeU column to bind Val-RS merely lowered the yield rather than affected the purification.
1284
BIOCHEMICAL
Vol. 60, No. 4,1974
it is imperative reaction. which
that the cognate
hours (16),
it seems likely
We are grateful
RESEARCH COMMUNICATIONS
tRNA remains aminoacylated
Since this takes place most aminoacyl-tRNA’s
AND BIOPHYSICAL
at pH 5 and room temperature,
have a half-life, that this condition
to the Science
with respect will
invariably
Research Council
during
the oxidation
conditions to hydrolysis,
under of several
be met.
for support.
REFERENCES 1. Beikirch H., von de Hoar F. and Cramer F,. (1972) Eur.J.Biochem. 26, 182-190. 2. Robert-Gero M. and Waller J-P. (1972) Eur. J. Biochem. 2, 315-3m 3. Forrester P. I. and Hancock R. L. (1973) Can.J.Biochem. 51, 231-234. 0. D. and Kiselev L. L. (1968) Molekul.Biol. z>O-68. 4. Nelidova 5. Bartkowiak S. and Pawelkiewicz J. (1972) Biochim. Biophys.Acta 272, 137-140. 6. Remy P., Birmele’C. and Ebel J.-P. (1972) FEBS Lett. 2, 134-13’8T7. Hayashi H. (1973) J.Biochem. 74, 203-208. G., Remy P. and E&l J.-P. (1974) 8. Befort J. J., Befort N., Petrisszt Biochimie 56, 625-630. 9. Preiss J., Berg P., Ofengand E. J., Bergmann F. H. and Dieckmann M. (1959) Proc.Nat1.Acad.Sci.U.S. 45, 319-328. 10. Cramer F., von der Hoar F.and Schlimme E. (1968) FEBS Lett. 2, 136-139. 11. Zubay G. (1962) J.Mol.Biol. i, 347-356. 12. Zamecnik P. C., Stephenson M. L. and Scott J. F. (1960) Proc.Natl.Acad.Sci. U.S. 46, 811-822. 13. LamedR., Levin Y. and Wilchek M. (1973) Biochim.Biophys.Acta 304, 231-235. 139, 391398. 14. Wilkinson S. and Knowles J. R. (1974) Bi0chem.J. 15. Bonnet J. and Ebel J.-P. (1972) Eur.J.Biochem. 3135-344. 16. Hentzen D., Mandel P. and Garel J.-P. 0972) Bxchim.Biophys.Acta -’281 228-232.
1285
BIOCHEMICAL
AFFINITY CHROMATOGRAPHY SPECIFIC tRNA COLUMNS Catherine
September
RESEARCH COMMUNICATIONS
OF AMINOACYL-tRNA SYNTHETASES ON WITHOUT PRIOR PURIFICATION OF tRNA
M. Joyce and Jeremy
The Dyson Perrins Laboratory,
Received
AND BIOPHYSICAL
University
R. Knowles*
of Oxford,
Oxford
OX1 3QY,
U.K.
3,l.974
SUMMARY. A method is described for the purification of aminoacyl-tRNA synthetases by chromatography, using a column of tRNA lacking the cognate tRNA, followed by a column of the cognate tRNA. The ability of the enzyme to discriminate between cognate and non-cognate tRNA is exploited in a novel and rapid preparation of the two columns. The purification graphic
techniques
enzymes
is usually
tiresome,
in crude cell extracts.
particularly
helpful
So far, affinity natural
of aminoacyl-tRNA
synthetases largely
In such a situation
for synthetase
amino acids (l-3)
and tRNA
tRNA have proved
more satisfactory.
However
column
of pure tRNA cognate purification
have pointed
out that such methods are unable
recognises
general
features
affinity
columns:
lacking
the cognate
Y
Copyright All rights
0 1974
features
of all tRNA’s.
Present address:
Abbreviations:
one might expect
specific
a column tRNA,
(4-8);
of a single
to separate tRNA,
this latter
made use of a
(4,5,7)
did not achieve
Ebel and coworkers
the desired
a method
preceded
Harvard
University,
recognising
involving
two of tRNA
proteins.
Cambridge,
Phe-RS, phenylalan I-tRNA synthetase; similarly for other see Scheme. synthetases. tRNA &al , tRNAox, tRNAoxmed:
1278
(6)
synthetase,
by a column
to remove other tRNA-binding
Department of Chemistry, Mass.02138.
the use of the
from other enzymes
proposed
tRNA,
time.
of these the methods involving
those methods which
They therefore
should be
in a shorter
have involved
from this technique.
of pure cognate
by Academic Press, Inc. in any form reserved.
of reproduction
isolation
of these
chromatography
with the target enzyme
the dramatic
which
affinity
factors may be obtained
substrates,
single
chromato-
due to the low concentration
since larger purification
methods reported
by conventional
In this
Vol. 60, No. 4, 1974
BIOCHEMICAL
way yeast Phe-RS
was purified
Ser-RS to 8590%
purity
of the necessary
from non-cognate
this very distinction with tRNA; avoiding
to homogeneity
tRNA.
(between
it is possible
a laborious
(6) and more recently
A particular
cognate
to exploit
fractionation
pair of columns
requires
and non-cognate
the desired
of tRNA by physical
techniques.
the actual
sequence
achieving
in this way a considerable
advantage
of this system is that a pure enzyme preparation
specificity
can be achieved
synthetases
and crude
of reactions
cognate
tRNA,
susceptible
to oxidative
may be coupled separation
tRNA.
affinity
cleavage
so a borohydride
in subsequent
the cognate
tRNA susceptible,
thus providing
reactions.)
to differentiate
precedent;
several
(see e.g.:
11,12).
tRNA,
reduction
of crude
The resulting
of the and dialdehyde
48, thus achieving
both the
of one of the non-cognate out to prevent
of the aminoacyl
tRNA its
group leaves
and coupling
to the carrier
column.
aminoacylation
between
(9).
of the oxidised
to oxidation
since total
remains intact
(10) is carried
Hydrolysis
in its turn,
A further
out using unfractionated
and the production
removal
the second affinity
The use of the enzymic oxidation
of Sepharose
(In practice,
participation
matrix,
by sodium periodate
material,
at the 3’-terminus
tRNA this feature
from non-cognate
to the column
amino acid to a mixture
masks the -cis-glycol
derivative
tRNA during
is not required
is carried
thus
We have used
in both time and effort.
a single
in the non-cognate
separation,
and non-cognate
is coupled
When the reaction
columns.
may not be complete,
cognate
tRNA
saving
by adding
ta a hydrazide
of cognate
necessary
in which
temporarily
while
between
makes
in its interaction
this fact to effect
to discriminate
the separation
synthetase
species)
reaction
aminoacylation
rat liver
solely
aminoacyl-tRNA
the enzyme
tRNA,
RESEARCH COMMUNICATIONS
(8).
The preparation of cognate
AND BIOPHYSICAL
cognate
reaction
in conjunction
and non-cognate
methods for the purification
1279
tRNA
with periodate
is not without
of tRNA are based on this principle
Vol.
60,
No.
4, 1974
BIOCHEMICAL
AND
Mixed
a:
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
tRNA
charging
+RNA””
tRNA-Va’
b OA
(all
(Val-tRNAva’) Hd
6-Val
HO
b:
OH
oxidation
1
tRNAVa’ M
tRNA-“*’
+ HO
(tRNA-Val) ox
O-V&l
c:
tRNAVa’
coup1
ing
-
I
+
+ any HO
other
uncoupled
tRNAox
-Val
O-&II
$
separation
of
Sepharose I
e:
reduction
tRNA-Val
tRNAVa’
+ HO
(tRNA;;f;ed) HO
O-&l
OH
I
Scheme.
f:
discharging
g:
oxidation
Preparation
of and
of affinity
Val-tRNAVa’ coupling
and
1280
of tRNAVa’
anti-affinity
columns
tRNAs)
BIOCHEMICAL
Vol. 60, No. 4,1974
RESULTS AND
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
DISCUSSION
tRNA columns designed
for the purification
of Val-RS
were prepared
as shown
in the Scheme. When an impure enzyme column, higher
the elution capacity
However,
profile
gel electrophoresis
of tRNAVa’
Improved mixture
material Val-RS
purification
was achieved on a column
and concentrated;
relative
then chromatographed
on the tRNAVat
-Val
a single
protein
proteins.
the crude enzyme sample was applied
which
frontally.
A suitable (Fig.2);
column
: the enzyme
assays showed,
column
with other synthetases.
above)
by first subjecting
to other synthetases.
the much
from other tRNA-binding
of tRNA
Val
showed three major components.
since (as mentioned Val-RS
on the tRNA
demonstrating
compared
fractions
washed to remove non-bound
was pooled activity
for Val-RS
of the pooled
of separating
to chromatography
and the column
material
to be expected
*IS incapable
was chromatographed
shown in Fig. 1 was obtained,
of this column
This result was entirely
solution
eluted
This
as expected,
an increase
quantity
of this pool was
gel electrophoresis
of the
a The aminoacylation mixture contained: 104mM-trien-HCl buffer, pH 7.2, -%g(OAc)2 (IO,4 mM), KCI (10.4 mM), ATP (2.1 m/v!), valine (0.83 mM), crude E .Coli tRNA (1.67 mg/ml) (Wh a t man Biochemicals Maidstone, Kent, U.K.), and Val-RS (100-1000 /,runits/ml). After 2 h at 4 d C, the reaction was quenched by cooling in ice and the tRNA recovered by phenol extraction followed by ethanol precipitation. b tRNA was oxidised according to Remy et al. (6). c Qxidised tRNA was coupled to the carfiatrix (6) [commercial CNBrictivated Sepharose (Pharmacia, Uppsala, Sweden) derivatised, in accordance with the manufacturers’ instructions, with adipic acid dihydrazide (13).1. d Functionalised Sepharose was recovered by filtration, washed and treated with NaBH4 (6). The tRNA-containing washings were combined and the tRNA recovered by lyophilisation for use in the following stages. e Reduction of any residual oxidised tRNA was carried out using excess NaBH4 p r&mg tRNA) in lM-phosphate buffer, pH 7, for 2 h at room temperature in the dark. f The tRNA was dialysed against 0.1 M-glycine buffer, pH 10.3, for 5 h at Gem temperature. Typically the fiq:folumn comprised 6 ml (settled bed volume) Sepharose carrying and the second column 1 ml Sepharose carrying 1 r&ml ,$$leNA ’ .
1281
in
Vol. 60, No. 4, 1974
BIOCHEMICAL
cp.m in
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
c.pm in assay
assuy
0
Figures.
Elution
profiles
of tRNA columns
(for details
see text)
All columns were run using O.OSM-acetate buffer, pH 5.5, containing glycerol (10% v/v), bCl (IOmM), EDTA (0.1 mM), and P-mercaptoethanol (20mM). The enzyme samp Pe was a partially purified mixture containing Val-, Leu-, Met-, and Tyr-tRNA synthetases from B.Stearothermophilus (kind gift of Drs. K. Sargeant and A. Atkinson, Microbiological Research Establishment, Porton Down, Salisbury, Wilts., U.K.). After extensive washing to remove non-bound protein, the bound protein was eluted with a linear gradient (at c ) of KCI (O-1M). Fractions were assayed for Val-RS ( -t ), Leu-RS (+), and Tyr-RS ( 4) as described by Wilkinson and Knowles (14): A280 (- -. - . . e). Fractions marked w were pooled and concentrated.
fractions
containing
Val-RS
In principle, general provided
should
the separation
tRNA features
we achieved
not bind - however,
ASSESSMENT
AND
now showed a single of Val-RS
can be accomplished
that one column
For example,
activity
is capable a similar
from other enzymes which using any pair of specific
of retaining
Val-RS
result using a tRNA
see below),
major component.
followed
while Leu
by a tRNA
recognise
tRNA columns,
the other is not.
column Val
(to which Val-RS
column.
SCOPE OF THE METHOD
In this paper we have described
the successful 1282
development
and application
Vol.
60,
No.
of a method chromatography drawbacks
BIOCHEMICAL
4, 1974
for
the
purification
on specific of affinity
AND
BIOPHYSKAL
of an aminoacyl tRNA
columns.
chromatography,
tRNA Our
notably
synthetase
method the
RESEARCH
time
c.p.m. in assay
avoids and
effort
COMMUNICATIONS
using one
of the
main
expended
in
c.p.m. in assay
16000 ,-
8coo
c.p.m. in assay
0
5
IO Fraction
1283
15 Number
20
25
affinity
the
Vol. 60, No. 4, 1974
preparation
BIOCHEMICAL
of the ligand
to the affinity
matrix. concurrently
preparation
barely
enzyme,
(in this case, the purified Since the separation
takes place
to be coupled
from non-cognate
tRNA
for the two coupling
reactions.
complete
of the target
described
did not effect still
being detectable
the reactions
upon which
depends
(in particular
the charging
and this results in some overlap
the separation reaction
degree
that,
purification
the entire
on gel electrophoresis. of cognate
This is
from non-cognate
tRNA
to completion,
of the two columns.
Nevertheless,
of purification
with further
column,
(15)) may not proceed
in specificity
that a very substantial
is reason to believe
of cognate
tRNA)
the time required
because
there
cognate
of the first affinity
minor contaminants
it is clear
RESEARCH COMMUNICATIONS
with the preparation
exceeds
The columns
AND BIOPHYSICAL
refinement
has been achieved, of the method,
and
this could
be
improved. Application be possible,
of this method
subject
to the following
First, the desired
problem
but unable
in attempting
both Val-RS
heterologous similar
amino
Secondly,
one from the other. of Leu-RS: with,
e.g.,
In this situation, satisfactory separation
mischarging
of co-purifying
We encountered
the tRNALeU Tyr-RS)
errors are more frequent,
for the successful
should also
tRNA;
capable
tRNA Val by B.Stearothermophilus
acids are concerned. should permit
only its cognate
a pair of columns
(compared
of E.Coli
system, charging
the same organism
*
to separate
and Leu-RS strongly
to be due to mischarging
must charge
produce
the purification
synthetases
conditions.
synthetase
of a second tRNA species would two synthetases
to other aminoacyl-tRNA
particularly
column
this
retained
(Fig.3).
This seems
Leu-RS. where
In a
chemically
use of enzyme and tRNA
application of cognate
,
from
of our method.* from non-cognate
tRNA,
Val As mentioned above, this tRNALeU column was used in conjunction with a tRNA column in the purification of Val-RS; in this case the ability of the tRNALeU column to bind Val-RS merely lowered the yield rather than affected the purification.
1284
BIOCHEMICAL
Vol. 60, No. 4,1974
it is imperative reaction. which
that the cognate
hours (16),
it seems likely
We are grateful
RESEARCH COMMUNICATIONS
tRNA remains aminoacylated
Since this takes place most aminoacyl-tRNA’s
AND BIOPHYSICAL
at pH 5 and room temperature,
have a half-life, that this condition
to the Science
with respect will
invariably
Research Council
during
the oxidation
conditions to hydrolysis,
under of several
be met.
for support.
REFERENCES 1. Beikirch H., von de Hoar F. and Cramer F,. (1972) Eur.J.Biochem. 26, 182-190. 2. Robert-Gero M. and Waller J-P. (1972) Eur. J. Biochem. 2, 315-3m 3. Forrester P. I. and Hancock R. L. (1973) Can.J.Biochem. 51, 231-234. 0. D. and Kiselev L. L. (1968) Molekul.Biol. z>O-68. 4. Nelidova 5. Bartkowiak S. and Pawelkiewicz J. (1972) Biochim. Biophys.Acta 272, 137-140. 6. Remy P., Birmele’C. and Ebel J.-P. (1972) FEBS Lett. 2, 134-13’8T7. Hayashi H. (1973) J.Biochem. 74, 203-208. G., Remy P. and E&l J.-P. (1974) 8. Befort J. J., Befort N., Petrisszt Biochimie 56, 625-630. 9. Preiss J., Berg P., Ofengand E. J., Bergmann F. H. and Dieckmann M. (1959) Proc.Nat1.Acad.Sci.U.S. 45, 319-328. 10. Cramer F., von der Hoar F.and Schlimme E. (1968) FEBS Lett. 2, 136-139. 11. Zubay G. (1962) J.Mol.Biol. i, 347-356. 12. Zamecnik P. C., Stephenson M. L. and Scott J. F. (1960) Proc.Natl.Acad.Sci. U.S. 46, 811-822. 13. LamedR., Levin Y. and Wilchek M. (1973) Biochim.Biophys.Acta 304, 231-235. 139, 391398. 14. Wilkinson S. and Knowles J. R. (1974) Bi0chem.J. 15. Bonnet J. and Ebel J.-P. (1972) Eur.J.Biochem. 3135-344. 16. Hentzen D., Mandel P. and Garel J.-P. 0972) Bxchim.Biophys.Acta -’281 228-232.
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