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Possible evolutionary steps in the genetic code
Vol. 107, No. 1, 1982 July 16, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 225-228
POSSIBLE EVOLUTIONARY STEPS IN THE GENETIC CODE Thomas H. Jukes Space Sciences Laboratory University of California, Berkeley Berkeley, CA 94720 Received
May
24,
1982
In mammalian mitochondrial codes, fourfold codons wobble-oair with UNN anticodons so that U wobbles with U, C, A and G. Twofold oyrimidine-terminated codons pair with GNN and twofold purine-terminated codons pair with UNN. lhese properties enable a prediction to be made for evolution of the universal genetic code. It was postulated (1) that an archetypal code of 16 quartets coded for 15 amino acids. If this code used UNN anticodons, then duplication of tRNA genes, followed by mutations in the anticodons and aminoacylation sites, would give rise to the present universal code.
Tqe genetic genetic
code
of codons
code in mitochondria (2,
with
in the
anticodon, having
with
U, such
wobble
of codons
proposal currently cases,
rules
findings
"lost"
in which
an anticodon
place
(2).
phenylalanine,
these
between
Also,
U
amino
UUY, pair and amino
acids
CAR, pair
with
anticodons
examples
follow
ciassical
acids that
other
two codons
a pathway
I suggested
an earlier
to a single
15 amino
to postulate
form.
pyrimidine-terminated the
takes
universa
("quartets")
such as phenylalanine,
Both
the
groups
codons
such as glutamine,
glutamine.
from
tKNA with
pairing
G, such as GAA for
possible
from
was the suggestion have
fourfold
by a singie
codons
codons,
universal
was assigned only
that
U, C, A and G in four
with
make it
have evolved
include
is
respects
(3).
present
code might
valine,
U, such as UUG for
pairing
code to its
would
starting
in certain
translated
two pyrimidine-terminated
with
These
are
with
two purine-terminated
starting
differences
as UAC for
wobbling
an anticodon
having
One of the
such as GUN, valine,
starting
acids
3).
differs
archetypal
amino rather the
(4)
that code
acid
(Table
than
the
doublets
of codons, in the
expansion universal
in which
20.
acids
of the genetic
each quartet
The archetypai
present amino
codon
the
i).
archetypal
(one
for
Embodied
were
and have,
those
code in the that
in eight
case of isoleucine)
in a
0006-291X/82/130225-04$01.00/0 225
Copyright 0 1982 by Academic Press, Inc. AN rights of reproduction in any form reserved.
Vol. 107, No. 1, 1982 quartet
to another
BIOCHEMICAL amino
histidine
was formerly
histidine
and the
If code
archetypal is
that
mutational
tRNA,
of this
in yeast
in its
nature
fairly
the present
three
anticodons
with
anticodon
UAC.
CCA without
Trp
the
amino
The archetypal to GUA, pairing an anticodon,
acid
tyrosine
with
for
code.
by which
the anticodon duplicate
evidently
with
has taken
use of CUN for
leucine
as in the
universal
1).
to produce,
for
respectively,
when the Trp
which
retained
originally
coded
anticodon
UAU and UAC.
did
anticodon
place
and the
fourth
retaining
mutated
to
include tRNAsVal,
from
UCA to
UCA was therefore
duplicate
lost,
so
when a duplication
tRNAs underwent
a mutation
UAU, was "recaptured"
by
by AUN. not
duplicate,
The two codons
and became chain-terminating
code (5).
four
tRNAMet was formed
and one of the
would
recently
example,
anticodon
tRNA and the anticodon The present
steps
A
while
of the code took
Subsequent
with
place
of leucine,
(Table
underwent
UUA and UUG.
instead
code
anticodon
became charged
Thus tRNA paired
expansion
postulatior
with
The second it
the
The first
tRNAphe,
so that
mitochondrial
threonine
was formed
The other,
the steps
UUU and UUC.
the
place,
the
In one of these,
site,
acid
trace
universal
tRNAs.
with
that
the archetypal
procedures,
codon.
now codes
use CUN for
of the
tRNA took
UAU to CAU.
isoleucine,
example,
GAC, CAC and IAC,
duplication
former
present
and mutations
UGA became a stop
of its from
tRNA
the
acceptance
the
that
Thus,
procedure to
in amino
universal
duplications
possible
UAA.
simple
additional
is
the anticodon
has retained
By these
of codons
the pairing
aminoacylation
These
function.
glutamine.
two identical
mitochondria.
Neurospora
for
UAA to GAA, pairing
and retained
change
it
to form
to form
change
leucine,
that
codons,
code expanded
from
acid,
code embodied
an archetypal
mutated
by the quartet
amino
fourfold
UAA, duplicated
form
"new"
RESEARCH COMMUNICATIONS
or to a chain-terminating
coded
the archetypal
uses for
acid
AND BIOPHYSICAL
codons
but
mutated
UAA and UAG were because
they
from
left
UUA
without
had lost
cognate
tRNA. An analogous mitochondrial no tRNA pairing
event
seems recently
code in which with
them is
to have occurred
in the mammalian
AGA and AGG have become chain-terminating in the human, 226
bovine
or mouse mitochondrial
codons
and
genomes
Vol. 107, No. 1, 1982
BIOCHEMICAL Table
1.
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Proposed Archetypal Genetic Code and Subsequent Evolution (From Ref. 1) Archetypal Assignments
Quartet ____-
Present Assignments
UUN
Phe
UUY-Phe UUR-Leu
CUN
Leu
No change
AUN
Ile
AUY-Ile AUA-Ile AUG-Met
GUN UCN CCN ACN GCN UAN
Val Ser Pro Thr Ala Tyr
No change No change No change No change No change UAY-Tyr UAR-CT
CAN
His
CAY-His CAR-Gln
AAN
Asn
AAY-Asn AAR-Lys
GAN
ASP
GAY-Asp GAR-Glu
UGN
CYS
UGY-Cys UGA-CT UGG-Tro
CGN AGN
Arg Ser
No change AGY-Ser AGR-Arg
GUY
No change
GGN
N = A, G, CT = chain
(6, It
7). is
These also
codons
noteworthy and
to
evolutionary
earlier
are
that
both
tryptophan
C or U; Y = U or termination
still
used
mitochondria
use
AUA and AUG for stages
in
for
C;
arginine both
methionine, the
R = A or
in
UGA and for
universal
G;
yeast UGG as
these
code
as
mitochondria
two
codes
for
examples
proposed
(5).
correspond
above.
ACKNOWLEDGEMENTS Support
from
NASA
Grant
NGR
05-003-460
and
the
assistance
of
Carol
Fegte
are
acknowledged.
REFERENCES _____ 1. Jukes, Press, 2.
Barrell,
T.H. (1968) in Molecules N.Y., p. 68.B.G.,
Anderson,
S.,
and Evolution Bankier,
A.T.,
227
de
(Second
printing),
Bruijn,
M.H.L.,
Columbia Chen,
E.,
Univ
BIOCHEMICAL
Vol. 107, No. 1, 1982
AND BIOPHYSICAL
Coulson, A.R., Drouin, J., Eperon, F ., Schreier, P.H., Smith, A.J.H., Natl. Acad. Sci. USA 77, 3164-3166. 3. Jukes,
T.H.
4. Crick,
F.H.C.
(1981) (1966)
J.
Mol. J. Mol.
Evol.
RESEARCH COMMUNICATIONS
I.C., Nierlich, D.P., Staden, R. and Young, 18,
Biol.
Roe, B.A., Sanger, I.G. (1980) Proc.
15-17.
19,
548-555.
5. Bonitz, S.B., Berlani, R., Coruzzi, G., Li, M., Macino, G., Nobrega, B.E. and Tzagoloff, A. (1980) Proc. F.B., Nobrega, M.P., Thalenfeld, Acad. Sci. USA 77, 3167-3170.
Natl.
6. Anderson, S., Bankier, A.T., Barrell, B.G., de Bruijn, M.H.L., Coulson, A.R., Drouin, J., Eperon, I.C., Nierlich, D.P., Roe, B.A., Sanger, F., Schreier, P.H., Smith, A.J.H., Staden, R. and Young, I.G. (1981) Nature 29J, 457-470. 7. Bibb, M.J., D.A. (1981)
Van Etten, R.A., Cell 26, 167-180.
Wright,
C.T.,
228
Walberg,
M.W. and Clayton,
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 225-228
POSSIBLE EVOLUTIONARY STEPS IN THE GENETIC CODE Thomas H. Jukes Space Sciences Laboratory University of California, Berkeley Berkeley, CA 94720 Received
May
24,
1982
In mammalian mitochondrial codes, fourfold codons wobble-oair with UNN anticodons so that U wobbles with U, C, A and G. Twofold oyrimidine-terminated codons pair with GNN and twofold purine-terminated codons pair with UNN. lhese properties enable a prediction to be made for evolution of the universal genetic code. It was postulated (1) that an archetypal code of 16 quartets coded for 15 amino acids. If this code used UNN anticodons, then duplication of tRNA genes, followed by mutations in the anticodons and aminoacylation sites, would give rise to the present universal code.
Tqe genetic genetic
code
of codons
code in mitochondria (2,
with
in the
anticodon, having
with
U, such
wobble
of codons
proposal currently cases,
rules
findings
"lost"
in which
an anticodon
place
(2).
phenylalanine,
these
between
Also,
U
amino
UUY, pair and amino
acids
CAR, pair
with
anticodons
examples
follow
ciassical
acids that
other
two codons
a pathway
I suggested
an earlier
to a single
15 amino
to postulate
form.
pyrimidine-terminated the
takes
universa
("quartets")
such as phenylalanine,
Both
the
groups
codons
such as glutamine,
glutamine.
from
tKNA with
pairing
G, such as GAA for
possible
from
was the suggestion have
fourfold
by a singie
codons
codons,
universal
was assigned only
that
U, C, A and G in four
with
make it
have evolved
include
is
respects
(3).
present
code might
valine,
U, such as UUG for
pairing
code to its
would
starting
in certain
translated
two pyrimidine-terminated
with
These
are
with
two purine-terminated
starting
differences
as UAC for
wobbling
an anticodon
having
One of the
such as GUN, valine,
starting
acids
3).
differs
archetypal
amino rather the
(4)
that code
acid
(Table
than
the
doublets
of codons, in the
expansion universal
in which
20.
acids
of the genetic
each quartet
The archetypai
present amino
codon
the
i).
archetypal
(one
for
Embodied
were
and have,
those
code in the that
in eight
case of isoleucine)
in a
0006-291X/82/130225-04$01.00/0 225
Copyright 0 1982 by Academic Press, Inc. AN rights of reproduction in any form reserved.
Vol. 107, No. 1, 1982 quartet
to another
BIOCHEMICAL amino
histidine
was formerly
histidine
and the
If code
archetypal is
that
mutational
tRNA,
of this
in yeast
in its
nature
fairly
the present
three
anticodons
with
anticodon
UAC.
CCA without
Trp
the
amino
The archetypal to GUA, pairing an anticodon,
acid
tyrosine
with
for
code.
by which
the anticodon duplicate
evidently
with
has taken
use of CUN for
leucine
as in the
universal
1).
to produce,
for
respectively,
when the Trp
which
retained
originally
coded
anticodon
UAU and UAC.
did
anticodon
place
and the
fourth
retaining
mutated
to
include tRNAsVal,
from
UCA to
UCA was therefore
duplicate
lost,
so
when a duplication
tRNAs underwent
a mutation
UAU, was "recaptured"
by
by AUN. not
duplicate,
The two codons
and became chain-terminating
code (5).
four
tRNAMet was formed
and one of the
would
recently
example,
anticodon
tRNA and the anticodon The present
steps
A
while
of the code took
Subsequent
with
place
of leucine,
(Table
underwent
UUA and UUG.
instead
code
anticodon
became charged
Thus tRNA paired
expansion
postulatior
with
The second it
the
The first
tRNAphe,
so that
mitochondrial
threonine
was formed
The other,
the steps
UUU and UUC.
the
place,
the
In one of these,
site,
acid
trace
universal
tRNAs.
with
that
the archetypal
procedures,
codon.
now codes
use CUN for
of the
tRNA took
UAU to CAU.
isoleucine,
example,
GAC, CAC and IAC,
duplication
former
present
and mutations
UGA became a stop
of its from
tRNA
the
acceptance
the
that
Thus,
procedure to
in amino
universal
duplications
possible
UAA.
simple
additional
is
the anticodon
has retained
By these
of codons
the pairing
aminoacylation
These
function.
glutamine.
two identical
mitochondria.
Neurospora
for
UAA to GAA, pairing
and retained
change
it
to form
to form
change
leucine,
that
codons,
code expanded
from
acid,
code embodied
an archetypal
mutated
by the quartet
amino
fourfold
UAA, duplicated
form
"new"
RESEARCH COMMUNICATIONS
or to a chain-terminating
coded
the archetypal
uses for
acid
AND BIOPHYSICAL
codons
but
mutated
UAA and UAG were because
they
from
left
UUA
without
had lost
cognate
tRNA. An analogous mitochondrial no tRNA pairing
event
seems recently
code in which with
them is
to have occurred
in the mammalian
AGA and AGG have become chain-terminating in the human, 226
bovine
or mouse mitochondrial
codons
and
genomes
Vol. 107, No. 1, 1982
BIOCHEMICAL Table
1.
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Proposed Archetypal Genetic Code and Subsequent Evolution (From Ref. 1) Archetypal Assignments
Quartet ____-
Present Assignments
UUN
Phe
UUY-Phe UUR-Leu
CUN
Leu
No change
AUN
Ile
AUY-Ile AUA-Ile AUG-Met
GUN UCN CCN ACN GCN UAN
Val Ser Pro Thr Ala Tyr
No change No change No change No change No change UAY-Tyr UAR-CT
CAN
His
CAY-His CAR-Gln
AAN
Asn
AAY-Asn AAR-Lys
GAN
ASP
GAY-Asp GAR-Glu
UGN
CYS
UGY-Cys UGA-CT UGG-Tro
CGN AGN
Arg Ser
No change AGY-Ser AGR-Arg
GUY
No change
GGN
N = A, G, CT = chain
(6, It
7). is
These also
codons
noteworthy and
to
evolutionary
earlier
are
that
both
tryptophan
C or U; Y = U or termination
still
used
mitochondria
use
AUA and AUG for stages
in
for
C;
arginine both
methionine, the
R = A or
in
UGA and for
universal
G;
yeast UGG as
these
code
as
mitochondria
two
codes
for
examples
proposed
(5).
correspond
above.
ACKNOWLEDGEMENTS Support
from
NASA
Grant
NGR
05-003-460
and
the
assistance
of
Carol
Fegte
are
acknowledged.
REFERENCES _____ 1. Jukes, Press, 2.
Barrell,
T.H. (1968) in Molecules N.Y., p. 68.B.G.,
Anderson,
S.,
and Evolution Bankier,
A.T.,
227
de
(Second
printing),
Bruijn,
M.H.L.,
Columbia Chen,
E.,
Univ
BIOCHEMICAL
Vol. 107, No. 1, 1982
AND BIOPHYSICAL
Coulson, A.R., Drouin, J., Eperon, F ., Schreier, P.H., Smith, A.J.H., Natl. Acad. Sci. USA 77, 3164-3166. 3. Jukes,
T.H.
4. Crick,
F.H.C.
(1981) (1966)
J.
Mol. J. Mol.
Evol.
RESEARCH COMMUNICATIONS
I.C., Nierlich, D.P., Staden, R. and Young, 18,
Biol.
Roe, B.A., Sanger, I.G. (1980) Proc.
15-17.
19,
548-555.
5. Bonitz, S.B., Berlani, R., Coruzzi, G., Li, M., Macino, G., Nobrega, B.E. and Tzagoloff, A. (1980) Proc. F.B., Nobrega, M.P., Thalenfeld, Acad. Sci. USA 77, 3167-3170.
Natl.
6. Anderson, S., Bankier, A.T., Barrell, B.G., de Bruijn, M.H.L., Coulson, A.R., Drouin, J., Eperon, I.C., Nierlich, D.P., Roe, B.A., Sanger, F., Schreier, P.H., Smith, A.J.H., Staden, R. and Young, I.G. (1981) Nature 29J, 457-470. 7. Bibb, M.J., D.A. (1981)
Van Etten, R.A., Cell 26, 167-180.
Wright,
C.T.,
228
Walberg,
M.W. and Clayton,