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Relation between structure and the degree of hydration for cobalt(II) bonded to nucleoside 5′-monophosphates
BIOCHEMICAL
Vol. 82, No. 1, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages 92-98
May ?5,1978
RELATIONBETWEEN STRUCTURE AND THEDEGREE OF HYDRATIONFOR COBALT(I1) BONDED TO NIJCLEOSIDE 5'-MONOPHOSPHATES
D.M.L. Goodgame, Chemistry
Yarch
Received
Department,
G.A.
Leach,
Imperial
and 2. Warnke"'
College,
London
SW? 2AY, U.K.
28,1978
SUMMARY: The variation of coordination geometry with degree of hydration has been studied for cobalt(I1) bonded to 5'-AMP, 5'-GMP, 5'-IMP, 5'-UMP, and 5'-CMP. Pink compounds with octahedral coordination about the metal ions were isolated but partial dehydration results in conversion to blue compounds containing tetrahedral cobalt. The ease of conversion is markedly dependent on the identity of the nucleotide. In the case of CoII-5'-AMP warming in water at 34'C is sufficient to cause the change to the tetrahedral form. Spectral results are given and some possible implications to the behaviour of cobalt-containing metalloenzymes, such as Co-RNA polymerase from E. coli, are briefly discussed.
INTRODUCTION: ition
and other
Much of this
from
zinc
that
in
appreciable
of several
solutions
in studies
for
with
geometry.
The metal
-ordinated
(5),
but
five ion
cobalt
[Co(5'-CMP)(HzO)],
' Present
geometry
address:
around
components
the metal
nucleotide is
frequently
RNA polymerase
molecules
the nucleotide
chain
coordination
geometry
completing
structure
is bound is
adopted. in which
trans-
(1,Z). sites
ion,
We have
derivatives
isolated
(3).
We have observed cobalt
an octahedral is also
In contrast,
via
of Chemistry,
ooos-291x/78/0821-0092$oi,oo/o Copyright 0 I978 by Academic Press, Inc. All rights of reproduction in any form reserved.
92
The University,
(4)
to N7
coordination octahedrally
phosphate
5'-CMP ion
binds
forms
cooxygens a
has a tetrahedral
(6).
Institute Poland.
in
used as a replacement
to the metal
the metal
of
of the bonding
[Co,(5'-UMP),(H20)~]10H,0
and a polymeric complex,
coordination
and [CO(~'-IMP)(H~O)~].~H~O
water in
and their
Cobalt
example,
[CO(~'-GMP)(H~O)~]~H~O
of the purine,
acids
cobalt(II)
at pH S7. of,
in the
on the determination
and on the
the structures
interest
to nucleic
has centred
molecules
aqueous
for
is
heavy metals
interest
the biological reported
There
80216
Gdansk,
Vol. 82, No. 1, 1978
This coupled
change with
tetrahedral gate for
&~~HEMI~AL
in geometry
our somewhat geometry
more closely a range
geometry vironment changes substrate
with
AND BI~PHY~ICAL
the lower
unexpected
with
5'-AMP
the relationship
about
a metal
in cell in the
on changing
processes
geometry
might
hydration
observation
between
of the 5'-CMP
that
even in aqueous
of cobalt(II)-ribonucleotide
hydration
of the biological
can adopt
has led
Facile
a
us to investigeometry
changes
of
to a more hydrophobic
to result
molecule
compound
and coordination
a water-rich
be expected
cobalt(I1)
media
compounds. from
RESEARCH COMMUNICATIONS
en-
in accompanying
containing
it
and/or
its
recognition.
mTERIALS AND METHODS: The disodium salts of 5'-AMP (Cambrian), 5'-GMP (Aldrich), 5'-IMP (Sigma), 5'-CMP and 5'-UMP (Koch-Light) and cobalt(I1) nitrate hexahydrate (BDH) were used without further purification. Except where stated solution of the disodium was added, with stirring, 1 mmole) in water (5 ml) case of 5'-AMP and 5'-CMP) 60'~ for 15 mins and then off, washed with a little complex was kept and the 3 hours and then storing the complexes turned from
below, the complexes were prepared as follows : A salt of the nucleotide (1.0 mmole) in water (10 ml) to one of cobalt nitrate hexahydrate (0.291 g, to produce a pink solution (or precipitate in the at pH 6-7. The solution (or mixture) was warmed at cooled to room temperature. The solid was filtered ice-cold water and air dried. One half of the remainder dehydrated by heating to 60°C --in vacua for in a desiccator over silica gel. Upon dehydration, pink to deep blue.
In the case of 5'-AMP, heating the suspension/solution of the pink complex produced a deep blue solid which remained blue on cooling. This was collected and dried as described above. When the reaction mixture was not heated a gelatinous pink solid was obtained, but this lost water so readily on exposure to the air that analyses could not be obtained for the original pink complex, but only for the resultant blue solid. case, cool. large ficient
The Co(5'-CME') complex showed similar the pink colour slowly returned as However, elemental analyses showed quantity of occluded water and even water to cause conversion to the
behaviour on heating but, in this the aqueous mixture was allowed to that the pink solid contained a very air drying was found to remove sufblue form.
Infrared spectra were recorded as Nujol mulls between caesium iodide plates using a Perkin-Elmer 257 spectrophotometer (4000-625 cm-l). Diffuse electronic reflectance spectra were obtained using a Beckmann DK2 spectrophotometer (350-2500 nm) and electron paramagnetic resonance spectra on a Varian El2 e.p.r. spectrometer. Pregl analyses Imperial College.
were
RESULTS AND DISCUSSION:
carried
out
by the Microanalytical
The formulae
and the analytical
93
Laboratory,
results
of the
com-
BIOCHEMICAL
Vol. 82, No. 1, 1978
plexes
we have
were
also
isolated
used to confirm
5'-IMP,
and 5'-UMP.
eotides
and that
those
on which
for
this
X-ray
approach
is
of essentially
as compared
[CO(~'-IMP)(H,O)~]~H~O)
assignments
is
and derived
band energies
these
compounds
The environments tigated
by examining
1% doping)
into
plexes
of 5'-GM?
several
transitions
is
expected
when
suitable
for
spectra
environments. hydrated
II,
given
in Table
of the metal
compounds
are
spectrum results
together
(of for
all
with
the band
ions
in these
compound.
close
gave
e.p.r.
to the g
the effects
compounds
have
eff
the environment
dehydration
the manganese
a tetrahedral
1).
Numerical
geometry results
compounds
were
doped
Manganese(I1)
ions
in
spectra
showing
= 2 region
for
splitting
(Figure are
2).
studies
94
inves-
(nominal
the pink
com-
splitting
of
hyperfine
Such a spectrum
finite
of one N7 of the purine
signals
further
ions
and formation
hyperfine
with
of manganese(I1)
of zero-field
shown by the X-ray
dehydrated
11.
cobalt
and 5'-IMP
partly
in Figure
the host
molecules,
complexes,
also
Co(5'-IMP)H,O
spectra
water
was
the electronic
1 and the numerical
associated
e.p.r.
be the case for
suit-
geometry
particularly
fully
in Table
out,
form
A representative
of the blue,
the
would
Upon partial
are given
their
tetrahedral
the pink,
intensities
of blue are
with
carried
crystalline
about are
nucl-
parameters.
and the high
the spectrum
in
between
shown in Figure
the spectra
(see
be obtained
geometries.
compounds
In contrast,
spectra.
distinction
octahedral
nucleotide
and infrared
ions
three
shown to be the same as
patterns
information
5'-GMP,
these
been
not
of all
were
with
with
had previously
Cobalt(I1)
spectra
compounds
compounds
5'-CMP
experiments
studies
studies,
a clear
in octahedral
The reflectance
the cobalt
could
methods.
as there
of the metal
typical
powder
X-ray
by spectral
with
Thermogravimetric of the
of the pink
structural
the new compounds
1.
contents
complex
X-ray
single-crystal
obtained
in Table
the water
of the blue
of their
Because
given
The samples
full
by comparisons
able
are
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
but unit
small, and five
(4). of the analogous collapsed
to give
blue
tetrahedral
a broad,
as
BIOCHEMICAL
Vol. 82, No. 1, 1978
Table I.
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Microanalyses of the Cobalt(II)-Nucleotide % FOUND COLOUR
Co(5'-AMP)H,O Co(5'-CMP) .2H20 Co(5'-GMP).8HzO Co(5'-GMP).2HsO Co(5'-IMP).7HzO Co(5'-IMP).H20 Co(5'-UMP).8H20 Co(5'-UMP).3H20
Table II.
% CALCULATED C H I
C
H
Blue Blue
28.04 25.72
2.88
28.45
3.34
Pink Blue
21.76 27.61
3.92 4.88
25.97 21.29
3.88 5.00
Pink Blue
22.50 28.74
3.97 4.37
26.33 22.61
3.54 4.74
Pink Blue
20.43 24.94
3.21 5.11
28.38 20.58
3.84
24.84
3.10 5.18 3.94
Electronic Reflectance Spectra of the Cobalt(II)-Nucleotide Compounds
Pink (Octahedral) 'T$P)
Complexes
f ?
VJCLEOTIDI
L
Compounds
*g
+ 'Tlg(F)
cm-'
cm-l
5'-AMP
19230
5'-CM!?
19050
15630 15870
5'-GMP 5'-IMP
19230 19610
15870 16260
5'-IJMP
19230
14600
Blue (Tetrahedral)
6850
775 885 0.91
Complexes
NUCLEOTIDE 5'-AMP
17700
6850
5'-CMP 5'-GMP 5'-IMP 5'-UMP
17390 17390
6860 7140 + 7140 7140 +
17390 17860
R
+ Not observed. ' Value only approximate due to the broad nature of the band.
95
Vol. 82, No. 1, 1978
BIOCHEMICAL
AND BIOPHYSICAL
I 20000
I I0000
I 25000
RESEARCH COMMUNICATIONS
I 5000
cm’.’
Figure
1.
relatively
(c)
featureless
- an effect
interactions ions.
results
original
pink
compound
via
version purine
takes
tetrahedral
that
from
N3 and phosphate dehydration form, studied.
place
even
cobalt(II)
which
and the host,
geometry
structure
on removal
has been are
strong
dipolar
paramagnetic
the tetrahedral
the metals
;
indicates
octahedral
structure
in which
Na2(5’-IMP)
a monomeric,
to a polymeric
Such a polymeric
nucleotides
species
a change
compounds
to the blue
ions
therefore,
[Co(5'-CMP)(H20>],
Partial
all
from
molecules.
binding
the manganese(I1)
seems probable,
complexes
water
absorption
between
It
spectra Of: (a) Co(5'-IMP).HzO.
Electronic (reflectance) (b) Co(5'-IMP).7H20;
in the blue
structure
in
the
of some of the
found
linked
cobalt
(6)
for
the blue
by nucleotides
groups.
of the occurs
cobalt(U) very
Indeed in water
derivative
much more readily the formation
on gentle
complexes
of 5'-AMP,
with
96
of the blue,
warming other
than
(I\, 34'C)
and its
with
con-
the other
polymeric whereas
organic or inorganic
virtually
ligands
BIOCHEMICAL
Vol. 82, No. 1, 1978
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
I mT
440
Figure
are
2.
X-Band e.p.r. spectra (b) Co(Mn)(5'-IMF').H~O (1% nominal Mn doping
relatively
either
unstable
by simple
replacement
Some further suspending
in water
addition
and water
of
-IMP
the pink
cobalt-5'-AMP,
-ca.
to octahedral
or by a combination
(with
3-4 hrs
were
(a)]
species of ligand
to the blue
5'-UMP
ease of dehydration
compounds
as a reasonable
typical for
made of the
cobalt-nucleotide
(chosen
s 5'-CMP
molecules
tests
The ease of conversion
> 5'-GMP
converted
of
addition.
I-methylpentane-2,4-diol onment).
and are
of water
qualitative
samples
ofr (a> Co(W(5'-IMP),7H,O; [instrumental gain 5 x that in each case).
model
at 36'C in
of a non-aqueous
form was:
by
5'-AMp
>> 5'-IJI-ip minutes
conversion
times
of several
and -*ca
1 day for
5'-IMP,
for
envir> 5'for
samples
of
% 30 mg). The spectral complex
biological
and other systems
observations in several
we report respects.
97
here Electronic
have relevance spectroscopy
to more of
BIOCHEMICAL
Vol. 82, No. 1, 1978
the metal enzymes
centres (7)
cobalt
enriched
ogue,
RNA-polymerase both
d(pT)Xo,
but
nucleoside
presumably
coordination
in
from were
shows bands
(8)
cm-'
has been proposed
on enzyme-substrate For example
E. coli
found
of cobalt-containing geometry
such spectra
demonstrated.
the 17,100
in which
metals
structural
or enzyme
the spectrum
at
to be perturbed
~17,100
of
and
by a template
band was influenced
anal-
by the addition
in
the nature
the extent of the
the cobalt-nucleotide
from
octahedral
with
which
these
metalloenzymes.
to tetrahedral coordination Secondly,
and the attendant dependent
tion
conditions.
then
this
ion
process.
might
upon the If well
(Co or 2n in the RNA-polymerase
and functional
to consider
by changes
clearly
only
intrinsic
have
important
geometry
of which
studies
of
triphosphates.
As these
is
changes
have been
cm-'
used in
tetrahedral'
Moreover
interaction
% 14,200
frequently
and a 'nearly
in many cases. -template
has been
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
this provide
roles
to which
in gene
medium.
compounds
we have
on partial changes
could
the potential structural identity selectivity at least
in
also
their
at the metal
unit in
in,
for
geometry the
ease
centres
moiety under
of such
are
given
the biological example,
ACRNOWLEDGEMENTSr We thank the Science Research Council for Studentship (to G.A.L.) and the British Council for a Research 2.W.).
hydrasystem
a recognit-
a Research Scholarship
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8.
Hodgson, D.J. (1977) Progr. Inorg. Chem. 23, 211-254. Marzilli, L.G. (1977) Progr. Inorg. Chem. 23, 255-378. Wu, C-W, Wu, F.Y-H., and Speckhard, D.C. (1977) Biochem. 16, 5449-5454. De Meester, P., Goodgame, D.M.L., Jones, T.J., and Skapski, A.C. (1974) C.R. Acad. SC. Paris, Ser. C, 279, 667-669. Cartwright, B.A., Goodgame, D.M.L., Jeeves, I., and Skapski, A.C. (1977) Biochim. Biophys. Acta 477, 195-198. Clark, G.R. and Orbell, J.D. (1975) J.C.S. Chem. Commun. 697-698. Lindskog, S. (1970) Struct. Bonding (Berlin) 8, 153-196, and refs therein. Speckhard, D.C., Wu, F-Y-H., and Wu, C-W. (1977) Biochem. 16, 5228-5234. 98
way
in coordination
the organic
prevails
one factor
facile
demonstrates
the nucleotide
it
be influenced
change
such changes
changes of
studied
occur
for
will
(3)
The particularly
dehydration
above)
transcription
such processes
solvation
quoted
(to
Vol. 82, No. 1, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages 92-98
May ?5,1978
RELATIONBETWEEN STRUCTURE AND THEDEGREE OF HYDRATIONFOR COBALT(I1) BONDED TO NIJCLEOSIDE 5'-MONOPHOSPHATES
D.M.L. Goodgame, Chemistry
Yarch
Received
Department,
G.A.
Leach,
Imperial
and 2. Warnke"'
College,
London
SW? 2AY, U.K.
28,1978
SUMMARY: The variation of coordination geometry with degree of hydration has been studied for cobalt(I1) bonded to 5'-AMP, 5'-GMP, 5'-IMP, 5'-UMP, and 5'-CMP. Pink compounds with octahedral coordination about the metal ions were isolated but partial dehydration results in conversion to blue compounds containing tetrahedral cobalt. The ease of conversion is markedly dependent on the identity of the nucleotide. In the case of CoII-5'-AMP warming in water at 34'C is sufficient to cause the change to the tetrahedral form. Spectral results are given and some possible implications to the behaviour of cobalt-containing metalloenzymes, such as Co-RNA polymerase from E. coli, are briefly discussed.
INTRODUCTION: ition
and other
Much of this
from
zinc
that
in
appreciable
of several
solutions
in studies
for
with
geometry.
The metal
-ordinated
(5),
but
five ion
cobalt
[Co(5'-CMP)(HzO)],
' Present
geometry
address:
around
components
the metal
nucleotide is
frequently
RNA polymerase
molecules
the nucleotide
chain
coordination
geometry
completing
structure
is bound is
adopted. in which
trans-
(1,Z). sites
ion,
We have
derivatives
isolated
(3).
We have observed cobalt
an octahedral is also
In contrast,
via
of Chemistry,
ooos-291x/78/0821-0092$oi,oo/o Copyright 0 I978 by Academic Press, Inc. All rights of reproduction in any form reserved.
92
The University,
(4)
to N7
coordination octahedrally
phosphate
5'-CMP ion
binds
forms
cooxygens a
has a tetrahedral
(6).
Institute Poland.
in
used as a replacement
to the metal
the metal
of
of the bonding
[Co,(5'-UMP),(H20)~]10H,0
and a polymeric complex,
coordination
and [CO(~'-IMP)(H~O)~].~H~O
water in
and their
Cobalt
example,
[CO(~'-GMP)(H~O)~]~H~O
of the purine,
acids
cobalt(II)
at pH S7. of,
in the
on the determination
and on the
the structures
interest
to nucleic
has centred
molecules
aqueous
for
is
heavy metals
interest
the biological reported
There
80216
Gdansk,
Vol. 82, No. 1, 1978
This coupled
change with
tetrahedral gate for
&~~HEMI~AL
in geometry
our somewhat geometry
more closely a range
geometry vironment changes substrate
with
AND BI~PHY~ICAL
the lower
unexpected
with
5'-AMP
the relationship
about
a metal
in cell in the
on changing
processes
geometry
might
hydration
observation
between
of the 5'-CMP
that
even in aqueous
of cobalt(II)-ribonucleotide
hydration
of the biological
can adopt
has led
Facile
a
us to investigeometry
changes
of
to a more hydrophobic
to result
molecule
compound
and coordination
a water-rich
be expected
cobalt(I1)
media
compounds. from
RESEARCH COMMUNICATIONS
en-
in accompanying
containing
it
and/or
its
recognition.
mTERIALS AND METHODS: The disodium salts of 5'-AMP (Cambrian), 5'-GMP (Aldrich), 5'-IMP (Sigma), 5'-CMP and 5'-UMP (Koch-Light) and cobalt(I1) nitrate hexahydrate (BDH) were used without further purification. Except where stated solution of the disodium was added, with stirring, 1 mmole) in water (5 ml) case of 5'-AMP and 5'-CMP) 60'~ for 15 mins and then off, washed with a little complex was kept and the 3 hours and then storing the complexes turned from
below, the complexes were prepared as follows : A salt of the nucleotide (1.0 mmole) in water (10 ml) to one of cobalt nitrate hexahydrate (0.291 g, to produce a pink solution (or precipitate in the at pH 6-7. The solution (or mixture) was warmed at cooled to room temperature. The solid was filtered ice-cold water and air dried. One half of the remainder dehydrated by heating to 60°C --in vacua for in a desiccator over silica gel. Upon dehydration, pink to deep blue.
In the case of 5'-AMP, heating the suspension/solution of the pink complex produced a deep blue solid which remained blue on cooling. This was collected and dried as described above. When the reaction mixture was not heated a gelatinous pink solid was obtained, but this lost water so readily on exposure to the air that analyses could not be obtained for the original pink complex, but only for the resultant blue solid. case, cool. large ficient
The Co(5'-CME') complex showed similar the pink colour slowly returned as However, elemental analyses showed quantity of occluded water and even water to cause conversion to the
behaviour on heating but, in this the aqueous mixture was allowed to that the pink solid contained a very air drying was found to remove sufblue form.
Infrared spectra were recorded as Nujol mulls between caesium iodide plates using a Perkin-Elmer 257 spectrophotometer (4000-625 cm-l). Diffuse electronic reflectance spectra were obtained using a Beckmann DK2 spectrophotometer (350-2500 nm) and electron paramagnetic resonance spectra on a Varian El2 e.p.r. spectrometer. Pregl analyses Imperial College.
were
RESULTS AND DISCUSSION:
carried
out
by the Microanalytical
The formulae
and the analytical
93
Laboratory,
results
of the
com-
BIOCHEMICAL
Vol. 82, No. 1, 1978
plexes
we have
were
also
isolated
used to confirm
5'-IMP,
and 5'-UMP.
eotides
and that
those
on which
for
this
X-ray
approach
is
of essentially
as compared
[CO(~'-IMP)(H,O)~]~H~O)
assignments
is
and derived
band energies
these
compounds
The environments tigated
by examining
1% doping)
into
plexes
of 5'-GM?
several
transitions
is
expected
when
suitable
for
spectra
environments. hydrated
II,
given
in Table
of the metal
compounds
are
spectrum results
together
(of for
all
with
the band
ions
in these
compound.
close
gave
e.p.r.
to the g
the effects
compounds
have
eff
the environment
dehydration
the manganese
a tetrahedral
1).
Numerical
geometry results
compounds
were
doped
Manganese(I1)
ions
in
spectra
showing
= 2 region
for
splitting
(Figure are
2).
studies
94
inves-
(nominal
the pink
com-
splitting
of
hyperfine
Such a spectrum
finite
of one N7 of the purine
signals
further
ions
and formation
hyperfine
with
of manganese(I1)
of zero-field
shown by the X-ray
dehydrated
11.
cobalt
and 5'-IMP
partly
in Figure
the host
molecules,
complexes,
also
Co(5'-IMP)H,O
spectra
water
was
the electronic
1 and the numerical
associated
e.p.r.
be the case for
suit-
geometry
particularly
fully
in Table
out,
form
A representative
of the blue,
the
would
Upon partial
are given
their
tetrahedral
the pink,
intensities
of blue are
with
carried
crystalline
about are
nucl-
parameters.
and the high
the spectrum
in
between
shown in Figure
the spectra
(see
be obtained
geometries.
compounds
In contrast,
spectra.
distinction
octahedral
nucleotide
and infrared
ions
three
shown to be the same as
patterns
information
5'-GMP,
these
been
not
of all
were
with
with
had previously
Cobalt(I1)
spectra
compounds
compounds
5'-CMP
experiments
studies
studies,
a clear
in octahedral
The reflectance
the cobalt
could
methods.
as there
of the metal
typical
powder
X-ray
by spectral
with
Thermogravimetric of the
of the pink
structural
the new compounds
1.
contents
complex
X-ray
single-crystal
obtained
in Table
the water
of the blue
of their
Because
given
The samples
full
by comparisons
able
are
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
but unit
small, and five
(4). of the analogous collapsed
to give
blue
tetrahedral
a broad,
as
BIOCHEMICAL
Vol. 82, No. 1, 1978
Table I.
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Microanalyses of the Cobalt(II)-Nucleotide % FOUND COLOUR
Co(5'-AMP)H,O Co(5'-CMP) .2H20 Co(5'-GMP).8HzO Co(5'-GMP).2HsO Co(5'-IMP).7HzO Co(5'-IMP).H20 Co(5'-UMP).8H20 Co(5'-UMP).3H20
Table II.
% CALCULATED C H I
C
H
Blue Blue
28.04 25.72
2.88
28.45
3.34
Pink Blue
21.76 27.61
3.92 4.88
25.97 21.29
3.88 5.00
Pink Blue
22.50 28.74
3.97 4.37
26.33 22.61
3.54 4.74
Pink Blue
20.43 24.94
3.21 5.11
28.38 20.58
3.84
24.84
3.10 5.18 3.94
Electronic Reflectance Spectra of the Cobalt(II)-Nucleotide Compounds
Pink (Octahedral) 'T$P)
Complexes
f ?
VJCLEOTIDI
L
Compounds
*g
+ 'Tlg(F)
cm-'
cm-l
5'-AMP
19230
5'-CM!?
19050
15630 15870
5'-GMP 5'-IMP
19230 19610
15870 16260
5'-IJMP
19230
14600
Blue (Tetrahedral)
6850
775 885 0.91
Complexes
NUCLEOTIDE 5'-AMP
17700
6850
5'-CMP 5'-GMP 5'-IMP 5'-UMP
17390 17390
6860 7140 + 7140 7140 +
17390 17860
R
+ Not observed. ' Value only approximate due to the broad nature of the band.
95
Vol. 82, No. 1, 1978
BIOCHEMICAL
AND BIOPHYSICAL
I 20000
I I0000
I 25000
RESEARCH COMMUNICATIONS
I 5000
cm’.’
Figure
1.
relatively
(c)
featureless
- an effect
interactions ions.
results
original
pink
compound
via
version purine
takes
tetrahedral
that
from
N3 and phosphate dehydration form, studied.
place
even
cobalt(II)
which
and the host,
geometry
structure
on removal
has been are
strong
dipolar
paramagnetic
the tetrahedral
the metals
;
indicates
octahedral
structure
in which
Na2(5’-IMP)
a monomeric,
to a polymeric
Such a polymeric
nucleotides
species
a change
compounds
to the blue
ions
therefore,
[Co(5'-CMP)(H20>],
Partial
all
from
molecules.
binding
the manganese(I1)
seems probable,
complexes
water
absorption
between
It
spectra Of: (a) Co(5'-IMP).HzO.
Electronic (reflectance) (b) Co(5'-IMP).7H20;
in the blue
structure
in
the
of some of the
found
linked
cobalt
(6)
for
the blue
by nucleotides
groups.
of the occurs
cobalt(U) very
Indeed in water
derivative
much more readily the formation
on gentle
complexes
of 5'-AMP,
with
96
of the blue,
warming other
than
(I\, 34'C)
and its
with
con-
the other
polymeric whereas
organic or inorganic
virtually
ligands
BIOCHEMICAL
Vol. 82, No. 1, 1978
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
I mT
440
Figure
are
2.
X-Band e.p.r. spectra (b) Co(Mn)(5'-IMF').H~O (1% nominal Mn doping
relatively
either
unstable
by simple
replacement
Some further suspending
in water
addition
and water
of
-IMP
the pink
cobalt-5'-AMP,
-ca.
to octahedral
or by a combination
(with
3-4 hrs
were
(a)]
species of ligand
to the blue
5'-UMP
ease of dehydration
compounds
as a reasonable
typical for
made of the
cobalt-nucleotide
(chosen
s 5'-CMP
molecules
tests
The ease of conversion
> 5'-GMP
converted
of
addition.
I-methylpentane-2,4-diol onment).
and are
of water
qualitative
samples
ofr (a> Co(W(5'-IMP),7H,O; [instrumental gain 5 x that in each case).
model
at 36'C in
of a non-aqueous
form was:
by
5'-AMp
>> 5'-IJI-ip minutes
conversion
times
of several
and -*ca
1 day for
5'-IMP,
for
envir> 5'for
samples
of
% 30 mg). The spectral complex
biological
and other systems
observations in several
we report respects.
97
here Electronic
have relevance spectroscopy
to more of
BIOCHEMICAL
Vol. 82, No. 1, 1978
the metal enzymes
centres (7)
cobalt
enriched
ogue,
RNA-polymerase both
d(pT)Xo,
but
nucleoside
presumably
coordination
in
from were
shows bands
(8)
cm-'
has been proposed
on enzyme-substrate For example
E. coli
found
of cobalt-containing geometry
such spectra
demonstrated.
the 17,100
in which
metals
structural
or enzyme
the spectrum
at
to be perturbed
~17,100
of
and
by a template
band was influenced
anal-
by the addition
in
the nature
the extent of the
the cobalt-nucleotide
from
octahedral
with
which
these
metalloenzymes.
to tetrahedral coordination Secondly,
and the attendant dependent
tion
conditions.
then
this
ion
process.
might
upon the If well
(Co or 2n in the RNA-polymerase
and functional
to consider
by changes
clearly
only
intrinsic
have
important
geometry
of which
studies
of
triphosphates.
As these
is
changes
have been
cm-'
used in
tetrahedral'
Moreover
interaction
% 14,200
frequently
and a 'nearly
in many cases. -template
has been
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
this provide
roles
to which
in gene
medium.
compounds
we have
on partial changes
could
the potential structural identity selectivity at least
in
also
their
at the metal
unit in
in,
for
geometry the
ease
centres
moiety under
of such
are
given
the biological example,
ACRNOWLEDGEMENTSr We thank the Science Research Council for Studentship (to G.A.L.) and the British Council for a Research 2.W.).
hydrasystem
a recognit-
a Research Scholarship
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8.
Hodgson, D.J. (1977) Progr. Inorg. Chem. 23, 211-254. Marzilli, L.G. (1977) Progr. Inorg. Chem. 23, 255-378. Wu, C-W, Wu, F.Y-H., and Speckhard, D.C. (1977) Biochem. 16, 5449-5454. De Meester, P., Goodgame, D.M.L., Jones, T.J., and Skapski, A.C. (1974) C.R. Acad. SC. Paris, Ser. C, 279, 667-669. Cartwright, B.A., Goodgame, D.M.L., Jeeves, I., and Skapski, A.C. (1977) Biochim. Biophys. Acta 477, 195-198. Clark, G.R. and Orbell, J.D. (1975) J.C.S. Chem. Commun. 697-698. Lindskog, S. (1970) Struct. Bonding (Berlin) 8, 153-196, and refs therein. Speckhard, D.C., Wu, F-Y-H., and Wu, C-W. (1977) Biochem. 16, 5228-5234. 98
way
in coordination
the organic
prevails
one factor
facile
demonstrates
the nucleotide
it
be influenced
change
such changes
changes of
studied
occur
for
will
(3)
The particularly
dehydration
above)
transcription
such processes
solvation
quoted
(to