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Indications for a common evolutionary origin shown in the primary structure of three transfer RNAs
Vol.
24,
No. 5, 1966
BIOCHEMICAL
INDICATIONS
FOR
IN THE
PRIMARY
AND
BIOPHYSICAL
A COMMON
EVOLUTIONARY
STRUCTURE
OF THREE
Thomas
H.
RESEARCH
ORIGIN
COMMUNICATIONS
SHOWN
TRANSFER
RNAs.
divergence
of
Jukes
Space Sciences Laboratory University of California Berkeley, California’
Received
August
4, 1966
There
is
molecules
from
cation
followed
tiation
is
and
to
comparison of
polypeptide
with
the
as
The
present,
it
of
example It
some
as
a result
(sRNA) made
in
above. Supported
to
the
of two
partial
has
been
possible
to
indications
now
of
example, a,
them
the
p and
are
their
that
(1).
genetic
of
the
is
in
with
and
sequence
from
of
i nogen
point
mutations by
acid
sequences
been
and
archetype
by
tryps
direct
compared
hemoglobin,
and
its
changes
has
a common
Chymotryps
differen-
compatible
amino
chains
dupli-
secondary
these the
protein
the
deletions
myoglobin
origin
of
conserve
examine
y polypeptide
accepted
possible
for
related the
serine
to
(4), that
procedure
grant
NsG of
first
479
California,
base
and
tyrosine
the
for
the
to
compare
molecules,
the
used is
by
time
acid
of
sRNAs
similar
the
nucleic
discoveries
essential
University
the
widely
a manner
by
a manner
included
comparison
functionally
The
in
to
certain
diver-
i nogen
are
(2). is
(3),
molecule
not
means extent
necessary
has
of
is
by
process
For
this
place The
constraints
the
but
sequences
of
the
chains.
evolution
another
I
genes,
taken
differentiation.
of
role.
a result
gent
by
evolutionary has
functional
restricted
of
the
archetype
structure
the
that
a common by
tertiary
biological Up
evidence
all
sequences sRNA
the
protein
insertion
of
National Berkeley.
744
Aeronautics
the
primary
obtained
structures from
of
alanine
transfer
(5).
The
comparison
sequences arbitrary
RNA was
mentioned gaps
and
yeast,
Space
which
infer
Administration
Vol.
24, No.
5, 1966
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
I
Figure I. Comparison of possible secondary structures,for yeast alanine, serine, and tyrosine sRNAs (see text). “indicates suggested deletion of bases in serine sRNA. The proposed anticodons are shown in each case in complementary juxtaposition to messenger coding triplets, in conformation with the “wobble” hvoothesis (12).
/
C-0
G
Me IL1 ’ : ‘u G--u I / ‘0-C ’ \
A--“-G
/
‘C
\ rxi
L& L ‘c
,U’“lA \ I;
:-G-G-c-c I ,I I 111 \ T.U2
‘G
’ Lln2-
A’
+A Cld /
\ Y \
lU ”
IMe \ I-T-C’
-C-C-G(U) (A)
‘t-o-
WryI
C
:=:
,un2’G‘A, GOMe ’
/ G I * \
AC
\/
,un,G
LFG
C-C-G II II G-G-C
0, ’ “t?=:-c-G-“-C-C 111 II 111
,u-G’A Y
,I,
\
TtI/C
* ‘e
-
Ii
p-u
I C3G I GSA , ‘GS l-E-“.-;-
,+“: -G-C 2-z
Y
:
\ T-*2
Al
“HZ ‘U”z-WI;
UH2.A
MO 1 MI\\ C-C-G “I ,,I G-G-C
1;
P
,I/
lA
/ GOY,
\ II
\
.A
U”2
A’
A-hop \G--Y-A
I-G-A’
-C-A-“-
--c-c--u-(U)
IUI
IA)
that by
deletions alignment
portions nature not
of
is of
yet
of
genetic
material
homologous
presumed
to
their
function,
sufficient
for
portions have or the
been because
have of
taken the
place sequences.
preserved
either
the
accumulation
time of
745
during
lapse
enough
The due
to
evolution identity the
following randomly-occurring
as of
shown these
essential duplication
is point
Vol. 24, No. 5, 1966
mutations are 5
to
produce
readily (7)
BIOCHEMICAL
differences
perceptible
are
structure
et
al.
provide
an
evolutionary
sRNAs.
The
in
each
18
to
of 2
includes The
is
that
below.
It
three
in
serine
all
the
this
loop
and to
these
chains
phenomena
of
to
enable the
2
cytochrome
following
41-45
84
f:47-50,
--54-57
5:60-64,
--72-76 and
the
UUU
sequence
and
tyrosine
alanine exists
in
place from
contained
draws
attention 2 pairing
loop
in
between
corresponding three
alanine
loops sRNAs
are
”2”
loop
the
compared
it
13 and
for
746
loops
the
system sites.
proposed
h:65-7
I
back
have
evolution
and
the
sRNA in
2
in 24
The
serine as
shown
two
sRNA,
homologous
portion. in
between
other
alanine
model:
2: 13-24
just
is
present
numbering
in
pair,
Loops
during
deleted
sRNA
base is
in
at
common
which
residues,
one
Holley
2: 34-40
the
residues in
made
g-2
homology
s The
j&
sRNAs
the 12
to
be
by by
Reqions
upon
of
to
tyrosyl
same
deletion
&
in
28,
and the
shortened
sRNA.
features
8-9,
includes
by
to
seryl
evolutionary
(sRNA)
used
conformation
tyrosine
Connecting
(8),was
model
been
to
RNA
alanyl,
residues
comparisons
g2J-a
f
one
in
al.
yeast
has
from
51-53,
The
The
48
et
transfer
“cloverleaP’
that
25-27 a-
originally
complementary
the
extending
Cantor
The
regions
suggested
a trinucleotide
and
the
l2,
region of
the
Reqions
from
molecules.
with
of
the
alanyl
1.
in
77-83
region
sRNAs,
or
yeast
the
Figure
shown of
is
possess
b: E-
connecting
one
by
comparing in
are
sRNA,
a$-~,
deleted
for
shown
sRNAs,
gaps,
sRNAs
deletion
Both
(6)
for
modified
that
He1 ical
been
chains
proposed
model
except
the
three
Helical
composition,
globin
subsequently
regions
( 3 1,
explained
(3),
comparison
helical
as
the
base
compared.
Holley,
et al
in
when
A secondary
four
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the loops
to
a short
postulated implies
case in
expanded (3),
evidently
that
of
the
all
three
form,
omitting
compare
it
more
other
two
sRNA the closely
sRNAs.
evolutionary
homology
in
their
base
Vol. 24, No. 5, 1966
sequences
in
regions,
Table
loops,
and
correspondence
in
sequence
that
where
the
(Figure
a region
of
tary cistrons sequent
the
the
a helical one
member
the
complement the
the
base
of
the
two
A much has
more
system
recent
apparently
a piece
led of
of the
to
the DNA
gene
three that
terminal
of
duplication, the
sRNAs contained -CCA-OH
in
in
in
84 that
base is
are
the
added
747
a time
to
evolution only
excluding
or
serine have
been from
transcription.
I) these
into
different
comparison archetype. changes,
sRNAs.
The
transcribed the
by
Such
evolve
an
“2’
replacement
3 single-base
yeast
the
of
The from
in
distance
(Figure
Replacement
complementarity.
to
some
region
sRNAs
pair
changing
in
about
following
sub-
inserting
mutations,
two
the
sRNA
base
point
by
of
alanine
indications
U.
1 appears pairs,
at
at
character.
divergent
complemen-
involves
2 helical
helical
of table
mutation
two
followed
separation
point
bring
their
concept
subsequently
another
regions
preserving the
to
helical
then
There
A)
in
sRNAs.
This
Each
however,
archetype
of
pair.
another
(C or
common
point
sRNAs
a complementary
and
a G or
is,
the
archetype
replacing
by an A would
U the
with
by
base
the
while
the
proceed.
Us opposite
in
separated
base
of
tyrosine
duplication
cistron.
could
and
gene
mutation
the
There
underwent
in
structure
reoccurring
i ne
Else-
incidence
the
tyros
the
sRNAs.
extensive
that
and
base in
enable
agreement
archetype
a point
this
opposite would
ne
yeast
secondary
serine
of
includes
(6,7).
and
region
zwhich
indicates
course,
replaced
the
of
22
complementary
by
how
compositions in
of
complementary
base
procedure
is
pair
appropriate
seri
another
the
or
probably
the
connecting obvious
all
evolution
to
which
exists,
of
2 This
of
of
to
to
in
sequences
residues
sRNAs
common
view
most
64
only
during
primary
replacement
one
the
in
duplication
by
first region
contains
of
of
surprising
archetype
region
be
appears
and -- 41-k
gene
to
three
the
two
residues
all
from
common
found
occur
regions, The
in
(9)
not
helical
aligned.
al,
in
A problem
helical
is
evidently
these
to
from
sRNAs
--IO-12
for
from
three
extending
sequences
the
all
is
can
which
are
homology
region
proposed
for
This that
in
et
homology
mutations
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
deletions
all
Zamir
I).
the
I,
BIOCHEMICAL
from
numbering Analyses
a
Vol.
24, No.
5, 1966
Table
.L
I.
Homologous serine and
alignment tyrosine
Ala
PG G G C G u G >k,ku GMe
PG G c A A c U U G
PC U C u C G G U A GMe c 2
C C C U Y
G C
40
C
CAc G A G
A A G UHZ
;‘rGMe c 2
0
U
Aisop
A G G C GMe A 2 A
= 6-aminoisopentenyi
conventional the
(9)*
ones. proposed
The the A.
Base in
dupl
icat
ion,
could
be
(3, in
bases
changes
are that
parentheses;
of
sys tern
of bases
sRNAs,
presence
number
other
deletions,
indicated.
If
and
lead and
the
sRNAs
to if
G,
U,
comparisons
indeed
748
an
G G C G T Y
k(A)
k AMe C U C G c C C C C G G G A G A
:(A) U C C u G C A G U U G U C G
!H
gaps.
original evolved
the
and
--36-38 sequence
“invariant”
C,
by
e.g.
from
the
have
arisen
which
will length
from
are
Res idues
emphasized
second may
so,
C A G G T Y
Tv
C C
are is
the
C C G 9:G ;‘;T
abbreviations
the
differentiation
Ser
UH CM,2 G
64-68
A,
Ala
w W 3:i-i +:A U ?::;u SC C G G A C U C G U C C A
so
3 molecules from
alanine,
A G A C U G Y A AMe A2z Y C U U G A G A
includes
differentiate
may
yeast
4, 5).
(IO,ll);other
5)
formed
this
however,
4, all
in
COMMUNICATIONS
W
adenosine
anticodons
modified
are
other
The
identity
(.4)
of
kcUH2 U
60
sequences RNAs (3,
A G A Y U I G A Aisop A Y C U U U UOMe G G G C U U(C) U G C C C G CMe G
22
UH2 UH A2 A G G C GMe c 2 A
RESEARCH
Ser
Ziie G
G w
lH2
from
of base transfer
Vr
‘JH2
that
BIOPHYSICAL
Ser
C G U A G UH C2
are
AND
Ala
:kG 9:C G
lo
BIOCHEMICAL
*.
GMe2
It from
first
assumed and
serine
following
reveal
sRNA gene
the
greater
a common
is G,
than origin
this by
gene
l
Vol.
24,
No. 5, 1966
duplications,
BIOCHEMICAL
this
number
of
became
increased
might
anticodons
suggest
that by
AND
that
the
underwent
gene
dupl
BIOPHYSICAL
RESEARCH
genetic
code
differentiation
icat
Each
ions.
COMMUNICATIONS
evolved
as
the
duplication
from number
could
a small of
give
sRNAs rise
to
a new
anticodon. REFERENCES 1.
Ingram,
2.
1963.
v.M., Univ.
Press,
Hartley,
B.S., Nature
3.
4.
H.G., Edn.
5.
Madison,
Brown,
D.L.
0. 5 :422.
D;tting
Everett, and A.
and
H.
H.
1966
Abstracts,
Kung.
p.
1965, 221i
8.
Cantor,
C., press).
S.
Jaskunas
9.
Zamir,
A.,
R,W.
Halley
R-H., sot.
Il.
Biemann,
12.
Crick,
M.J.
Robins,
M.
L.
1965.
Marquisee, 147:1462. Chemie,
S.H.
international
Cold
Spring
31:43.
and E.L. Smith, Press, N.Y.),
and
M. Science
1965.
Angew.
Margoliash, E. (Academic
I.
Madison,
(Columbia
Smi 11 ie.
1966.
1965,
and
L.B.
Evolution
Feldman.
97.
Hall,
L.
and
and
J.T. Zamir.
p.
IO.
and Press,
Genetics 132.
Kauffmann
G.E. Everett and Symp. Quant. Biol. E.
in p.
Pauling. N.Y.),
7.
Zuckerkandl, (Academic
Hemoglobins Chapter 6,
J. Apgar, G.A. J.R. Penswick
J.T., Harbor
6.
J.R. 207:1157.
Ho1 ley, R.W., Merrell, Zachau,
The N.Y.)
in
in
Tinoco,
Evolving
Evolving
Genes
1966.
Jr..
1965.
Marquisee.
Stasiuk
and
Genes
R.
J.
J.
and
Proteins
and
Proteins
Mol.
Biol.
Biol.
Chem.
1966.
Thedford.
J.
(in
240:1267
Am.
88:2614. K.
F.H.C. manuscript.
and
S. 1965.
Tsunakawa.
1966.
Codon-anticodon
(cited pai ring
749
by -
Zachau, the
wobble
et
al.
the
1966).
hypothesis;
Chem.
24,
No. 5, 1966
BIOCHEMICAL
INDICATIONS
FOR
IN THE
PRIMARY
AND
BIOPHYSICAL
A COMMON
EVOLUTIONARY
STRUCTURE
OF THREE
Thomas
H.
RESEARCH
ORIGIN
COMMUNICATIONS
SHOWN
TRANSFER
RNAs.
divergence
of
Jukes
Space Sciences Laboratory University of California Berkeley, California’
Received
August
4, 1966
There
is
molecules
from
cation
followed
tiation
is
and
to
comparison of
polypeptide
with
the
as
The
present,
it
of
example It
some
as
a result
(sRNA) made
in
above. Supported
to
the
of two
partial
has
been
possible
to
indications
now
of
example, a,
them
the
p and
are
their
that
(1).
genetic
of
the
is
in
with
and
sequence
from
of
i nogen
point
mutations by
acid
sequences
been
and
archetype
by
tryps
direct
compared
hemoglobin,
and
its
changes
has
a common
Chymotryps
differen-
compatible
amino
chains
dupli-
secondary
these the
protein
the
deletions
myoglobin
origin
of
conserve
examine
y polypeptide
accepted
possible
for
related the
serine
to
(4), that
procedure
grant
NsG of
first
479
California,
base
and
tyrosine
the
for
the
to
compare
molecules,
the
used is
by
time
acid
of
sRNAs
similar
the
nucleic
discoveries
essential
University
the
widely
a manner
by
a manner
included
comparison
functionally
The
in
to
certain
diver-
i nogen
are
(2). is
(3),
molecule
not
means extent
necessary
has
of
is
by
process
For
this
place The
constraints
the
but
sequences
of
the
chains.
evolution
another
I
genes,
taken
differentiation.
of
role.
a result
gent
by
evolutionary has
functional
restricted
of
the
archetype
structure
the
that
a common by
tertiary
biological Up
evidence
all
sequences sRNA
the
protein
insertion
of
National Berkeley.
744
Aeronautics
the
primary
obtained
structures from
of
alanine
transfer
(5).
The
comparison
sequences arbitrary
RNA was
mentioned gaps
and
yeast,
Space
which
infer
Administration
Vol.
24, No.
5, 1966
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
I
Figure I. Comparison of possible secondary structures,for yeast alanine, serine, and tyrosine sRNAs (see text). “indicates suggested deletion of bases in serine sRNA. The proposed anticodons are shown in each case in complementary juxtaposition to messenger coding triplets, in conformation with the “wobble” hvoothesis (12).
/
C-0
G
Me IL1 ’ : ‘u G--u I / ‘0-C ’ \
A--“-G
/
‘C
\ rxi
L& L ‘c
,U’“lA \ I;
:-G-G-c-c I ,I I 111 \ T.U2
‘G
’ Lln2-
A’
+A Cld /
\ Y \
lU ”
IMe \ I-T-C’
-C-C-G(U) (A)
‘t-o-
WryI
C
:=:
,un2’G‘A, GOMe ’
/ G I * \
AC
\/
,un,G
LFG
C-C-G II II G-G-C
0, ’ “t?=:-c-G-“-C-C 111 II 111
,u-G’A Y
,I,
\
TtI/C
* ‘e
-
Ii
p-u
I C3G I GSA , ‘GS l-E-“.-;-
,+“: -G-C 2-z
Y
:
\ T-*2
Al
“HZ ‘U”z-WI;
UH2.A
MO 1 MI\\ C-C-G “I ,,I G-G-C
1;
P
,I/
lA
/ GOY,
\ II
\
.A
U”2
A’
A-hop \G--Y-A
I-G-A’
-C-A-“-
--c-c--u-(U)
IUI
IA)
that by
deletions alignment
portions nature not
of
is of
yet
of
genetic
material
homologous
presumed
to
their
function,
sufficient
for
portions have or the
been because
have of
taken the
place sequences.
preserved
either
the
accumulation
time of
745
during
lapse
enough
The due
to
evolution identity the
following randomly-occurring
as of
shown these
essential duplication
is point
Vol. 24, No. 5, 1966
mutations are 5
to
produce
readily (7)
BIOCHEMICAL
differences
perceptible
are
structure
et
al.
provide
an
evolutionary
sRNAs.
The
in
each
18
to
of 2
includes The
is
that
below.
It
three
in
serine
all
the
this
loop
and to
these
chains
phenomena
of
to
enable the
2
cytochrome
following
41-45
84
f:47-50,
--54-57
5:60-64,
--72-76 and
the
UUU
sequence
and
tyrosine
alanine exists
in
place from
contained
draws
attention 2 pairing
loop
in
between
corresponding three
alanine
loops sRNAs
are
”2”
loop
the
compared
it
13 and
for
746
loops
the
system sites.
proposed
h:65-7
I
back
have
evolution
and
the
sRNA in
2
in 24
The
serine as
shown
two
sRNA,
homologous
portion. in
between
other
alanine
model:
2: 13-24
just
is
present
numbering
in
pair,
Loops
during
deleted
sRNA
base is
in
at
common
which
residues,
one
Holley
2: 34-40
the
residues in
made
g-2
homology
s The
j&
sRNAs
the 12
to
be
by by
Reqions
upon
of
to
tyrosyl
same
deletion
&
in
28,
and the
shortened
sRNA.
features
8-9,
includes
by
to
seryl
evolutionary
(sRNA)
used
conformation
tyrosine
Connecting
(8),was
model
been
to
RNA
alanyl,
residues
comparisons
g2J-a
f
one
in
al.
yeast
has
from
51-53,
The
The
48
et
transfer
“cloverleaP’
that
25-27 a-
originally
complementary
the
extending
Cantor
The
regions
suggested
a trinucleotide
and
the
l2,
region of
the
Reqions
from
molecules.
with
of
the
alanyl
1.
in
77-83
region
sRNAs,
or
yeast
the
Figure
shown of
is
possess
b: E-
connecting
one
by
comparing in
are
sRNA,
a$-~,
deleted
for
shown
sRNAs,
gaps,
sRNAs
deletion
Both
(6)
for
modified
that
He1 ical
been
chains
proposed
model
except
the
three
Helical
composition,
globin
subsequently
regions
( 3 1,
explained
(3),
comparison
helical
as
the
base
compared.
Holley,
et al
in
when
A secondary
four
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
the loops
to
a short
postulated implies
case in
expanded (3),
evidently
that
of
the
all
three
form,
omitting
compare
it
more
other
two
sRNA the closely
sRNAs.
evolutionary
homology
in
their
base
Vol. 24, No. 5, 1966
sequences
in
regions,
Table
loops,
and
correspondence
in
sequence
that
where
the
(Figure
a region
of
tary cistrons sequent
the
the
a helical one
member
the
complement the
the
base
of
the
two
A much has
more
system
recent
apparently
a piece
led of
of the
to
the DNA
gene
three that
terminal
of
duplication, the
sRNAs contained -CCA-OH
in
in
in
84 that
base is
are
the
added
747
a time
to
evolution only
excluding
or
serine have
been from
transcription.
I) these
into
different
comparison archetype. changes,
sRNAs.
The
transcribed the
by
Such
evolve
an
“2’
replacement
3 single-base
yeast
the
of
The from
in
distance
(Figure
Replacement
complementarity.
to
some
region
sRNAs
pair
changing
in
about
following
sub-
inserting
mutations,
two
the
sRNA
base
point
by
of
alanine
indications
U.
1 appears pairs,
at
at
character.
divergent
complemen-
involves
2 helical
helical
of table
mutation
two
followed
separation
point
bring
their
concept
subsequently
another
regions
preserving the
to
helical
then
There
A)
in
sRNAs.
This
Each
however,
archetype
of
pair.
another
(C or
common
point
sRNAs
a complementary
and
a G or
is,
the
archetype
replacing
by an A would
U the
with
by
base
the
while
the
proceed.
Us opposite
in
separated
base
of
tyrosine
duplication
cistron.
could
and
gene
mutation
the
There
underwent
in
structure
reoccurring
i ne
Else-
incidence
the
tyros
the
sRNAs.
extensive
that
and
base in
enable
agreement
archetype
a point
this
opposite would
ne
yeast
secondary
serine
of
includes
(6,7).
and
region
zwhich
indicates
course,
replaced
the
of
22
complementary
by
how
compositions in
of
complementary
base
procedure
is
pair
appropriate
seri
another
the
or
probably
the
connecting obvious
all
evolution
to
which
exists,
of
2 This
of
of
to
to
in
sequences
residues
sRNAs
common
view
most
64
only
during
primary
replacement
one
the
in
duplication
by
first region
contains
of
of
surprising
archetype
region
be
appears
and -- 41-k
gene
to
three
the
two
residues
all
from
common
found
occur
regions, The
in
(9)
not
helical
aligned.
al,
in
A problem
helical
is
evidently
these
to
from
sRNAs
--IO-12
for
from
three
extending
sequences
the
all
is
can
which
are
homology
region
proposed
for
This that
in
et
homology
mutations
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
deletions
all
Zamir
I).
the
I,
BIOCHEMICAL
from
numbering Analyses
a
Vol.
24, No.
5, 1966
Table
.L
I.
Homologous serine and
alignment tyrosine
Ala
PG G G C G u G >k,ku GMe
PG G c A A c U U G
PC U C u C G G U A GMe c 2
C C C U Y
G C
40
C
CAc G A G
A A G UHZ
;‘rGMe c 2
0
U
Aisop
A G G C GMe A 2 A
= 6-aminoisopentenyi
conventional the
(9)*
ones. proposed
The the A.
Base in
dupl
icat
ion,
could
be
(3, in
bases
changes
are that
parentheses;
of
sys tern
of bases
sRNAs,
presence
number
other
deletions,
indicated.
If
and
lead and
the
sRNAs
to if
G,
U,
comparisons
indeed
748
an
G G C G T Y
k(A)
k AMe C U C G c C C C C G G G A G A
:(A) U C C u G C A G U U G U C G
!H
gaps.
original evolved
the
and
--36-38 sequence
“invariant”
C,
by
e.g.
from
the
have
arisen
which
will length
from
are
Res idues
emphasized
second may
so,
C A G G T Y
Tv
C C
are is
the
C C G 9:G ;‘;T
abbreviations
the
differentiation
Ser
UH CM,2 G
64-68
A,
Ala
w W 3:i-i +:A U ?::;u SC C G G A C U C G U C C A
so
3 molecules from
alanine,
A G A C U G Y A AMe A2z Y C U U G A G A
includes
differentiate
may
yeast
4, 5).
(IO,ll);other
5)
formed
this
however,
4, all
in
COMMUNICATIONS
W
adenosine
anticodons
modified
are
other
The
identity
(.4)
of
kcUH2 U
60
sequences RNAs (3,
A G A Y U I G A Aisop A Y C U U U UOMe G G G C U U(C) U G C C C G CMe G
22
UH2 UH A2 A G G C GMe c 2 A
RESEARCH
Ser
Ziie G
G w
lH2
from
of base transfer
Vr
‘JH2
that
BIOPHYSICAL
Ser
C G U A G UH C2
are
AND
Ala
:kG 9:C G
lo
BIOCHEMICAL
*.
GMe2
It from
first
assumed and
serine
following
reveal
sRNA gene
the
greater
a common
is G,
than origin
this by
gene
l
Vol.
24,
No. 5, 1966
duplications,
BIOCHEMICAL
this
number
of
became
increased
might
anticodons
suggest
that by
AND
that
the
underwent
gene
dupl
BIOPHYSICAL
RESEARCH
genetic
code
differentiation
icat
Each
ions.
COMMUNICATIONS
evolved
as
the
duplication
from number
could
a small of
give
sRNAs rise
to
a new
anticodon. REFERENCES 1.
Ingram,
2.
1963.
v.M., Univ.
Press,
Hartley,
B.S., Nature
3.
4.
H.G., Edn.
5.
Madison,
Brown,
D.L.
0. 5 :422.
D;tting
Everett, and A.
and
H.
H.
1966
Abstracts,
Kung.
p.
1965, 221i
8.
Cantor,
C., press).
S.
Jaskunas
9.
Zamir,
A.,
R,W.
Halley
R-H., sot.
Il.
Biemann,
12.
Crick,
M.J.
Robins,
M.
L.
1965.
Marquisee, 147:1462. Chemie,
S.H.
international
Cold
Spring
31:43.
and E.L. Smith, Press, N.Y.),
and
M. Science
1965.
Angew.
Margoliash, E. (Academic
I.
Madison,
(Columbia
Smi 11 ie.
1966.
1965,
and
L.B.
Evolution
Feldman.
97.
Hall,
L.
and
and
J.T. Zamir.
p.
IO.
and Press,
Genetics 132.
Kauffmann
G.E. Everett and Symp. Quant. Biol. E.
in p.
Pauling. N.Y.),
7.
Zuckerkandl, (Academic
Hemoglobins Chapter 6,
J. Apgar, G.A. J.R. Penswick
J.T., Harbor
6.
J.R. 207:1157.
Ho1 ley, R.W., Merrell, Zachau,
The N.Y.)
in
in
Tinoco,
Evolving
Evolving
Genes
1966.
Jr..
1965.
Marquisee.
Stasiuk
and
Genes
R.
J.
J.
and
Proteins
and
Proteins
Mol.
Biol.
Biol.
Chem.
1966.
Thedford.
J.
(in
240:1267
Am.
88:2614. K.
F.H.C. manuscript.
and
S. 1965.
Tsunakawa.
1966.
Codon-anticodon
(cited pai ring
749
by -
Zachau, the
wobble
et
al.
the
1966).
hypothesis;
Chem.