TY - JOUR
T1 - Nitroxide-nitroxide and nitroxide-metal distance measurements in transition metal complexes with two or three paramagnetic centres give access to thermodynamic and kinetic stabilities
AU - Giannoulis, Angeliki
AU - Ackermann, Katrin
AU - Spindler, Philipp
AU - Higgins, Catherine
AU - Cordes, David B.
AU - Slawin, Alexandra M. Z.
AU - Prisner, Thomas F.
AU - Bode, Bela E.
N1 - AG was supported by the EPSRC funded Centre for Doctoral Training in ‘integrated magnetic resonance’ (EP/J500045/1). BEB is grateful for funding from the European Union (REA 334496). This work was supported by the EPSRC (EP/M024660/1), the DFG (Schwerpunktprogramm 1601) and a Wellcome Trust multiuser equipment grant [099149/Z/12/Z].
PY - 2018/4/28
Y1 - 2018/4/28
N2 - Fundamentally, the stability of coordination complexes and of templated
(bio)macromolecular assemblies depends on the thermodynamic and kinetic
properties of the intermediates and final complexes formed. Here, we
used pulse EPR (electron paramagnetic resonance) spectroscopy to
determine the stabilities of nanoscopic assemblies formed between one or
two nitroxide spin-labelled tridentate 2,2′:6′,2′′-terpyridine (tpy)
ligands and divalent metal ions (FeII, ZnII, CoII and CuII).
In three distinct approaches we exploited (a) the modulation depth of
pulsed electron–electron double resonance (PELDOR) experiments in
samples with increasing metal-to-ligand ratios, (b) the frequencies of
PELDOR under broadband excitation using shaped pulses and (c) the
distances recovered from well-resolved PELDOR data in fully deuterated
solvents measured at 34 GHz. The results demonstrate that PELDOR is
highly sensitive to resolving the stability of templated dimers and
allows to readily distinguish anti-cooperative binding (for CuII ions) from cooperative binding (for CoII or FeII ions). In the case of paramagnetic ions (CoII and CuII)
the use of broadband PELDOR allowed to identify the cooperativity of
binding from the time domain and distance data. By using a second
labelled tpy ligand and by mixing two homoleptic complexes of the same
metal centre we could probe the kinetic stability on a timescale of tens
of seconds. Here, tpy complexes of CuII and ZnII were found to be substitutionally labile, CoII showed very slow exchange and FeII was inert under our conditions. Not only do our chemical models allow studying metal–ligand interactions via
PELDOR spectroscopy, the design of our study is directly transferable
to (bio)macromolecular systems for determining the kinetic and
thermodynamic stabilities underpinning (templated) multimerisation.
Considering the limited methods available to obtain direct information
on the composition and stability of complex assemblies we believe our
approach to be a valuable addition to the armoury of methods currently
used to study these systems.
AB - Fundamentally, the stability of coordination complexes and of templated
(bio)macromolecular assemblies depends on the thermodynamic and kinetic
properties of the intermediates and final complexes formed. Here, we
used pulse EPR (electron paramagnetic resonance) spectroscopy to
determine the stabilities of nanoscopic assemblies formed between one or
two nitroxide spin-labelled tridentate 2,2′:6′,2′′-terpyridine (tpy)
ligands and divalent metal ions (FeII, ZnII, CoII and CuII).
In three distinct approaches we exploited (a) the modulation depth of
pulsed electron–electron double resonance (PELDOR) experiments in
samples with increasing metal-to-ligand ratios, (b) the frequencies of
PELDOR under broadband excitation using shaped pulses and (c) the
distances recovered from well-resolved PELDOR data in fully deuterated
solvents measured at 34 GHz. The results demonstrate that PELDOR is
highly sensitive to resolving the stability of templated dimers and
allows to readily distinguish anti-cooperative binding (for CuII ions) from cooperative binding (for CoII or FeII ions). In the case of paramagnetic ions (CoII and CuII)
the use of broadband PELDOR allowed to identify the cooperativity of
binding from the time domain and distance data. By using a second
labelled tpy ligand and by mixing two homoleptic complexes of the same
metal centre we could probe the kinetic stability on a timescale of tens
of seconds. Here, tpy complexes of CuII and ZnII were found to be substitutionally labile, CoII showed very slow exchange and FeII was inert under our conditions. Not only do our chemical models allow studying metal–ligand interactions via
PELDOR spectroscopy, the design of our study is directly transferable
to (bio)macromolecular systems for determining the kinetic and
thermodynamic stabilities underpinning (templated) multimerisation.
Considering the limited methods available to obtain direct information
on the composition and stability of complex assemblies we believe our
approach to be a valuable addition to the armoury of methods currently
used to study these systems.
U2 - 10.1039/C8CP01611A
DO - 10.1039/C8CP01611A
M3 - Article
SN - 1463-9076
VL - 20
SP - 11196
EP - 11205
JO - Physical Chemistry Chemical Physics
JF - Physical Chemistry Chemical Physics
IS - 16
ER -