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High molecular weight complex formation of rat liver lysyl-tRNA synthetase reduces enzyme lability to thermal inactivation
Vol. 106, No. 1, 1982 May 14, 1982
BIOCHEMICAL
AND EIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 44-47
HIGH MOLECULAR WEIGHT COMPLEX FORMATION OF RAT LIVER LYSYL-tRNA REDUCES ENZYMF. LABILITY TO THERMAL INACTIVATION
SYNrHETASF
Chi V. Dang Department of Cell Biology and Anatomy The Johns Hopkins University School of Medicine Baltimore, Maryland 212n5 Received
March
22,
1982
Eukaryotic aminoacyl-tRNA synthetases tend to occur in high molecular weight multienzyme complexes in contrast to the prokaryotic counterparts. The functional significance of complex formation is not understood but stabilization of enzyme activities in the complex(es) has been suggested as one of many possible functions. We provide evidence that the 245 complex lysyl-tRNA synthetase activity is more resistant to thermal inactivation than the 6S free lysyl-tRNA synthetase activity at 30°, 37', and 43'C.
Introduction The aminoacyl-tRNA from amino
acid,
biosynthesis as high lo6
tRNA,
(1).
for
occurring
that
(2,
is presently
formation Recently
is it
molecular
has been suggested
We have reported 24s complex
(3)
and its
complex
for tend
weights
appear (11)
than
ubiquitous
250,000 in
and Drosophila
complexes
significance
thermal
(8)
chromatography of aminoacyl-
of these
advantage
formation
to occur
less
and affinity
from
protein
up to over
weights
yeast
activities
HMW com-
of complex inactivation.
may provide
inter-
(16).
isolation
disassembly
and characterization by hydrophobic
OOOS-291X/82/090044-U4$01.00/0 Copyright A II rrghls
molecular
One possible
that
in vivo -__ the
molecular
are multienzyme
understood.
acids
synthetases
from conventional
of enzyme
stabilization
from
The functional
5, 10).
stabilization
with
types
Evidence
not
with
of aminoacyl-tRNA
amino
The HMW complexes
4).
these HMW complexes
tRNA synthetases plexes
enzymes
in many cell (8).
activated
(HMW) complexes
see Ref.
the formation
aminoacyl-tRNA
to prokaryotic
to human placenta indicate
and ATP providing
weight
a review
eukaryotes
catalyze
The eukaryotic
molecular
in contrast
(l-18,
synthetases
0 1982 by Academic Press, Inc. of reproduction in any form reserved.
44
of a rat chromatography
liver to yield
Vol. 106, No. 1, 1982 free
6S enzymes
suggesting
that
lability
BIOCHEMICAL
(3,
We report
5).
complex
kinetics
in this
formation
of enzyme activity
activation
AND BIOPHYSICAL communication
of aminoacyl-tRNA
to thermal
and Methods
Materials:
Sources
for
materials
are
in vitro -__
synthetases
inactivation
evidence reduces
by comparing
of the 6s and 245 lysyl-tRNA
Materials
RESEARCH COMMUNICATIONS
synthetase
described
the
in-
activity.
previously
(2,
3, 5).
Enzyme Preparation and Assay: The rat liver 24s lysyl-tRNA synthetase was prepared in the presence of phenylmethane sulfonyl fluoride (PMSF) as described by Bang and Yang (3). The 6s lysyl-tR.NA synthetase was prepared by chromatography of the 24s complex on a diaminooctyl-Sepharose 4B column and centrifugation in a sucrose gradient as described (3, 5). Enzyme assays were according to (3) in presence of 3 mg/ml of bovine serum albumin which protects the enzyme activity completely at 37'C for at least 10 minutes. One unit of enzyme activity is that amount catalyzing the formation of 1 nmole of aminoacyl-tRNA in 1 minute at 37'C. Thermal Inactivation of Synthetase Activities: Pooled 245 lysyl-tRNA synthetase was diluted to give comparable concentration of enzyme activity (2-4 units/ml) as the pooled 6S enzyme. The 24s and 6s enzymes (1 ml each) were dialyzed in 1 liter of buffer (50 mM Tris-HCl (pH 7.5 at 25OC), 2 mM dithiothritol, 25 mM KCl, 5 mM MgC12, 0.2 mM PMSF) containing 10% glycerol at 4'C for 6 hours to assure identical buffer conditions. Aliquots (0.2 ml) of hS and 24s enz mes were incubated in 10 x 75 mm glass test tubes in water baths at 30°C, 37 8 C, and 43OC. Aliquots of 25 ~1 were removed at appropriate times and immediately assayed at 37'C for 5 minutes in presence of 3 mg/ml BSA. Results
and Discussion
The 24s lysyl-tRNA lysyl-tRNA
synthetase
Increasing
lability
increasing
temperatures,
rates
synthetase activity
of the
creased
rate
of
at 30°,
at 30'
of the
6s Lys-tRNA
first-order
at the
three
temperatures.
to be a residual
The results resistant and 43'C. inactivation The nature
show that
to thermal
The curvilinear suggest of this
synthetase
than
semilog
at the
the 6S
lA,
B, C).
is activity
activity
synthetase
plots
is not 45
understood,
in-
activity. appears
different activity
to the but
The
to he
synthetase
inactivates temperatures.
is more at 30°,
of the 24s Lys-tRYA in contrast
has similar
is a markedly
synthetase
three
seen with
the 6S enzyme activity
activity
activity
activity
there
than
(Figs.
The 24s Lys-tRNA
the 24s Lys-tRNA
a residual residual
At 43'C
activity
inactivation
labile
synthetase
of the 24s Lys-tRNA
rate
appears
synthetase
and 37'C.
inactivation
less
and 43'C
the 245 lys-tRNA
inactivation
to what
is
37',
6s Lys-tRNA
but
of inactivation
activity
37',
synthetase 6S enzyme. it
may result
Vol. 106, No. 1, 1982
BIOCHEMICAL
AND BIOPHYSICAL
Time
Fig.
1 Thermal
(minutes)
inactivation
of 24s (-0-O-j
and 6s (-0-O-j
activity
at 30°C (panel
A), 37'C (panel
synthetase (panel
RESEARCH COMMUNICATIONS
C).
The ordinate
of initial
activity
represents
remaining
the logarithm
after
a certain
lysyl-tRNA B), and 43'C of
percent
the
incubation
time
(abscissa).
from
the equilibrium
between
24s enzyme preparation. enzyme activity free
This
of the dimeric exchange
complex
with
(5,
of other
stabilization
has been Leu-tRNA
by Ile,
molecular
stabilization
inactivation
experiments
for
the
(17).
in the complexed
than
thermal
the
inactivation
The possibility
of
enzymes may now be more definitely purified
specific
interactions.
Chinese
in-
aminoacyl-tRNA
synthetase
Arg,
Tie,
and Leu (16). in the
Gln,
stability
Glu,
for
concept
of intermolecular
by -__ in vivo
studies.
A temperature-
hamster
This
synthetase
ovary
acid
suggests
the
complex
65 and 24s Lys-tRNA 46
(GHO) cell
amino
mutant
leucine
synthetase
has
and synergistically
occurrence
in vivo. -~
Leu,
the Lys-tRNA
This
by the homologous
with
for
(3) may provide
synthetase
Val,
the
inactivation
synthetase
synthetases
substantiated
to be protected
protected
may represent
to thermal
of highly
in the 24s complex by intermolecular
been shown
and free
synthetase
10).
synthetase
sensitive
Lys-tRNA
has been reported
the availability
The presence
activity
germ leucyl-tRYA
complexed
and free
resistant
phenomenon
preparation
Met and Pro
is more
wheat
between
vestigated
The residual
which
enzyme.
complexed
of inter-
The -___ in vitro in this
com-
BIOCHEMICAL
Vol. 106, No. 1, 1982 munication
show in vitro
formation.
The similar
activity
at 30'
previously summary,
observed
stabilization rates
of
with
of
in this
of synthetase inactivation
and a faster the rabbit
among the many possible
we demonstrate lability
and 37'C
AND BIOPHYSICAL
communication
the enzyme activities
rate
activity
by complex
of the 24s Lys-tRNA of inactivation
reticulocyte functions
RESEARCH COMMUNICATIONS
at 43OC have been
16s complex
(13).
of HMW aminoacyl-tRNA
that
complex
to thermal
formation
synthetase
In synthetases,
decreases
the
this
was
inactivation.
Acknowledgements The author thanks partially performed.
Dr.
D.C.H.
Yang,
in whose
lahoratory
work
References 1. 3. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.
Schimmel, P.R. and Sb'll, D. (1979) Ann. Rev. Biochem. 48, 601-648. Biochem. Biophys. Res. Commun. Dar%, C.V. and Yang, D.C.H. (1978) 80, 709-714. J. Biol. Chem. 254, 5350-5356. Da%, C.V. and Yang, D.C.H. (1979) Dang, C.V. and Yang, D.C.H. (1982) Int. 3. Biochem., in press. Johnson, D.L., Dang, C.V. and Yang, D.C.H. (1980) J. Biol. Chem. 255, 4362-4366. Johnson, D.L. and Yang, D.C.H. (1981) Proc. Nat. Acad. Sci., U.S.A. 78, 4059-4062. Bandyopadhyay, A.K. and Deutscher, M.P. (1971) J. Mol. Biol. 60, 113-122. Denney, R.M. (1977) Arch. Biochem. Biophys. 183, 157-167. Glinski, R.L., Gainey, P.C., Mawhinney, T.P., and Hilderman, R.H. (1979) Biochem. Biophys. Res. Commun. 88, 1052-1061. Keller-man, O., Brevet, A., Tonetti, H., and Wailer, J.-P. (1979) Eur. J. Biochem. 99, 541-550. Dimitrijevic, L. (1977) FEBS Lett. 79, 37-41. Shafer, S.J., Olexa, S. and Hillman, R. (1976) Insect. Biochem. 6, 405-411. Som, K. and Hardesty, B. (1975) Arch. Biochem. Biophys. 166, 507-517. Ussery, M.A., Tanaka, W.K. and Hardesty, B. (1977) Eur. J. Biochem. 72, 491-500. Vennegoor, C. and Bloemendal, H. (1972) Eur. .I. Biochem. 26, 462-473. Molnar, S.J. and Rauth, A.M. (1979) J. Cell.Physiol. 98, 315-326. Carias, J.R., Mouricout, M., Quintard, B., Thomas, J.C. and Julien, R. (1978) Eur. J. Biochem. 87, 583-590. Ritter, P.O., Enger, M.D. and Hampel, A.E. (1979) Biochim. Biophys. Acta 562, 377-385.
47
BIOCHEMICAL
AND EIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 44-47
HIGH MOLECULAR WEIGHT COMPLEX FORMATION OF RAT LIVER LYSYL-tRNA REDUCES ENZYMF. LABILITY TO THERMAL INACTIVATION
SYNrHETASF
Chi V. Dang Department of Cell Biology and Anatomy The Johns Hopkins University School of Medicine Baltimore, Maryland 212n5 Received
March
22,
1982
Eukaryotic aminoacyl-tRNA synthetases tend to occur in high molecular weight multienzyme complexes in contrast to the prokaryotic counterparts. The functional significance of complex formation is not understood but stabilization of enzyme activities in the complex(es) has been suggested as one of many possible functions. We provide evidence that the 245 complex lysyl-tRNA synthetase activity is more resistant to thermal inactivation than the 6S free lysyl-tRNA synthetase activity at 30°, 37', and 43'C.
Introduction The aminoacyl-tRNA from amino
acid,
biosynthesis as high lo6
tRNA,
(1).
for
occurring
that
(2,
is presently
formation Recently
is it
molecular
has been suggested
We have reported 24s complex
(3)
and its
complex
for tend
weights
appear (11)
than
ubiquitous
250,000 in
and Drosophila
complexes
significance
thermal
(8)
chromatography of aminoacyl-
of these
advantage
formation
to occur
less
and affinity
from
protein
up to over
weights
yeast
activities
HMW com-
of complex inactivation.
may provide
inter-
(16).
isolation
disassembly
and characterization by hydrophobic
OOOS-291X/82/090044-U4$01.00/0 Copyright A II rrghls
molecular
One possible
that
in vivo -__ the
molecular
are multienzyme
understood.
acids
synthetases
from conventional
of enzyme
stabilization
from
The functional
5, 10).
stabilization
with
types
Evidence
not
with
of aminoacyl-tRNA
amino
The HMW complexes
4).
these HMW complexes
tRNA synthetases plexes
enzymes
in many cell (8).
activated
(HMW) complexes
see Ref.
the formation
aminoacyl-tRNA
to prokaryotic
to human placenta indicate
and ATP providing
weight
a review
eukaryotes
catalyze
The eukaryotic
molecular
in contrast
(l-18,
synthetases
0 1982 by Academic Press, Inc. of reproduction in any form reserved.
44
of a rat chromatography
liver to yield
Vol. 106, No. 1, 1982 free
6S enzymes
suggesting
that
lability
BIOCHEMICAL
(3,
We report
5).
complex
kinetics
in this
formation
of enzyme activity
activation
AND BIOPHYSICAL communication
of aminoacyl-tRNA
to thermal
and Methods
Materials:
Sources
for
materials
are
in vitro -__
synthetases
inactivation
evidence reduces
by comparing
of the 6s and 245 lysyl-tRNA
Materials
RESEARCH COMMUNICATIONS
synthetase
described
the
in-
activity.
previously
(2,
3, 5).
Enzyme Preparation and Assay: The rat liver 24s lysyl-tRNA synthetase was prepared in the presence of phenylmethane sulfonyl fluoride (PMSF) as described by Bang and Yang (3). The 6s lysyl-tR.NA synthetase was prepared by chromatography of the 24s complex on a diaminooctyl-Sepharose 4B column and centrifugation in a sucrose gradient as described (3, 5). Enzyme assays were according to (3) in presence of 3 mg/ml of bovine serum albumin which protects the enzyme activity completely at 37'C for at least 10 minutes. One unit of enzyme activity is that amount catalyzing the formation of 1 nmole of aminoacyl-tRNA in 1 minute at 37'C. Thermal Inactivation of Synthetase Activities: Pooled 245 lysyl-tRNA synthetase was diluted to give comparable concentration of enzyme activity (2-4 units/ml) as the pooled 6S enzyme. The 24s and 6s enzymes (1 ml each) were dialyzed in 1 liter of buffer (50 mM Tris-HCl (pH 7.5 at 25OC), 2 mM dithiothritol, 25 mM KCl, 5 mM MgC12, 0.2 mM PMSF) containing 10% glycerol at 4'C for 6 hours to assure identical buffer conditions. Aliquots (0.2 ml) of hS and 24s enz mes were incubated in 10 x 75 mm glass test tubes in water baths at 30°C, 37 8 C, and 43OC. Aliquots of 25 ~1 were removed at appropriate times and immediately assayed at 37'C for 5 minutes in presence of 3 mg/ml BSA. Results
and Discussion
The 24s lysyl-tRNA lysyl-tRNA
synthetase
Increasing
lability
increasing
temperatures,
rates
synthetase activity
of the
creased
rate
of
at 30°,
at 30'
of the
6s Lys-tRNA
first-order
at the
three
temperatures.
to be a residual
The results resistant and 43'C. inactivation The nature
show that
to thermal
The curvilinear suggest of this
synthetase
than
semilog
at the
the 6S
lA,
B, C).
is activity
activity
synthetase
plots
is not 45
understood,
in-
activity. appears
different activity
to the but
The
to he
synthetase
inactivates temperatures.
is more at 30°,
of the 24s Lys-tRYA in contrast
has similar
is a markedly
synthetase
three
seen with
the 6S enzyme activity
activity
activity
activity
there
than
(Figs.
The 24s Lys-tRNA
the 24s Lys-tRNA
a residual residual
At 43'C
activity
inactivation
labile
synthetase
of the 24s Lys-tRNA
rate
appears
synthetase
and 37'C.
inactivation
less
and 43'C
the 245 lys-tRNA
inactivation
to what
is
37',
6s Lys-tRNA
but
of inactivation
activity
37',
synthetase 6S enzyme. it
may result
Vol. 106, No. 1, 1982
BIOCHEMICAL
AND BIOPHYSICAL
Time
Fig.
1 Thermal
(minutes)
inactivation
of 24s (-0-O-j
and 6s (-0-O-j
activity
at 30°C (panel
A), 37'C (panel
synthetase (panel
RESEARCH COMMUNICATIONS
C).
The ordinate
of initial
activity
represents
remaining
the logarithm
after
a certain
lysyl-tRNA B), and 43'C of
percent
the
incubation
time
(abscissa).
from
the equilibrium
between
24s enzyme preparation. enzyme activity free
This
of the dimeric exchange
complex
with
(5,
of other
stabilization
has been Leu-tRNA
by Ile,
molecular
stabilization
inactivation
experiments
for
the
(17).
in the complexed
than
thermal
the
inactivation
The possibility
of
enzymes may now be more definitely purified
specific
interactions.
Chinese
in-
aminoacyl-tRNA
synthetase
Arg,
Tie,
and Leu (16). in the
Gln,
stability
Glu,
for
concept
of intermolecular
by -__ in vivo
studies.
A temperature-
hamster
This
synthetase
ovary
acid
suggests
the
complex
65 and 24s Lys-tRNA 46
(GHO) cell
amino
mutant
leucine
synthetase
has
and synergistically
occurrence
in vivo. -~
Leu,
the Lys-tRNA
This
by the homologous
with
for
(3) may provide
synthetase
Val,
the
inactivation
synthetase
synthetases
substantiated
to be protected
protected
may represent
to thermal
of highly
in the 24s complex by intermolecular
been shown
and free
synthetase
10).
synthetase
sensitive
Lys-tRNA
has been reported
the availability
The presence
activity
germ leucyl-tRYA
complexed
and free
resistant
phenomenon
preparation
Met and Pro
is more
wheat
between
vestigated
The residual
which
enzyme.
complexed
of inter-
The -___ in vitro in this
com-
BIOCHEMICAL
Vol. 106, No. 1, 1982 munication
show in vitro
formation.
The similar
activity
at 30'
previously summary,
observed
stabilization rates
of
with
of
in this
of synthetase inactivation
and a faster the rabbit
among the many possible
we demonstrate lability
and 37'C
AND BIOPHYSICAL
communication
the enzyme activities
rate
activity
by complex
of the 24s Lys-tRNA of inactivation
reticulocyte functions
RESEARCH COMMUNICATIONS
at 43OC have been
16s complex
(13).
of HMW aminoacyl-tRNA
that
complex
to thermal
formation
synthetase
In synthetases,
decreases
the
this
was
inactivation.
Acknowledgements The author thanks partially performed.
Dr.
D.C.H.
Yang,
in whose
lahoratory
work
References 1. 3. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.
Schimmel, P.R. and Sb'll, D. (1979) Ann. Rev. Biochem. 48, 601-648. Biochem. Biophys. Res. Commun. Dar%, C.V. and Yang, D.C.H. (1978) 80, 709-714. J. Biol. Chem. 254, 5350-5356. Da%, C.V. and Yang, D.C.H. (1979) Dang, C.V. and Yang, D.C.H. (1982) Int. 3. Biochem., in press. Johnson, D.L., Dang, C.V. and Yang, D.C.H. (1980) J. Biol. Chem. 255, 4362-4366. Johnson, D.L. and Yang, D.C.H. (1981) Proc. Nat. Acad. Sci., U.S.A. 78, 4059-4062. Bandyopadhyay, A.K. and Deutscher, M.P. (1971) J. Mol. Biol. 60, 113-122. Denney, R.M. (1977) Arch. Biochem. Biophys. 183, 157-167. Glinski, R.L., Gainey, P.C., Mawhinney, T.P., and Hilderman, R.H. (1979) Biochem. Biophys. Res. Commun. 88, 1052-1061. Keller-man, O., Brevet, A., Tonetti, H., and Wailer, J.-P. (1979) Eur. J. Biochem. 99, 541-550. Dimitrijevic, L. (1977) FEBS Lett. 79, 37-41. Shafer, S.J., Olexa, S. and Hillman, R. (1976) Insect. Biochem. 6, 405-411. Som, K. and Hardesty, B. (1975) Arch. Biochem. Biophys. 166, 507-517. Ussery, M.A., Tanaka, W.K. and Hardesty, B. (1977) Eur. J. Biochem. 72, 491-500. Vennegoor, C. and Bloemendal, H. (1972) Eur. .I. Biochem. 26, 462-473. Molnar, S.J. and Rauth, A.M. (1979) J. Cell.Physiol. 98, 315-326. Carias, J.R., Mouricout, M., Quintard, B., Thomas, J.C. and Julien, R. (1978) Eur. J. Biochem. 87, 583-590. Ritter, P.O., Enger, M.D. and Hampel, A.E. (1979) Biochim. Biophys. Acta 562, 377-385.
47