The detection of bacterial spores via dipicolinate-triggered lanthanide luminescence has been improved in terms of detection limit, stability, and susceptibility to interferents by use of lanthanide−macrocycle binary complexes. Specifically, we compared the effectiveness of Sm, Eu, Tb, and Dy complexes with the macrocycle 1,4,7,10-tetraazacyclododecane-1,7-diacetate (DO2A) to the corresponding lanthanide aquo ions. The Ln(DO2A)^+ binary complexes bind dipicolinic acid (DPA), a major constituent of bacterial spores, with greater affinity and demonstrate significant improvement in bacterial spore detection. Of the four luminescent lanthanides studied, the terbium complex exhibits the greatest dipicolinate binding affinity (100-fold greater than Tb^(3+) alone, and 10-fold greater than other Ln(DO2A)^+ complexes) and highest quantum yield. Moreover, the inclusion of DO2A extends the pH range over which Tb−DPA coordination is stable, reduces the interference of calcium ions nearly 5-fold, and mitigates phosphate interference 1000-fold compared to free terbium alone. In addition, detection of Bacillus atrophaeus bacterial spores was improved by the use of Tb(DO2A)^+, yielding a 3-fold increase in the signal-to-noise ratio over Tb^(3+). Out of the eight cases investigated, the Tb(DO2A)^+ binary complex is best for the detection of bacterial spores

Cable, Morgan L.

Gray, Harry B.

Kirby, James P.

Levine, Dana J.

Manary, Micah J.

Ponce, Adrian

English

Caltech Authors - Main

S1 
Supporting Information 
 
Detection of Bacterial Spores with Lanthanide-Macrocycle Binary 
Complexes 
 
Morgan L. Cable,§† James P. Kirby,† Dana J. Levine,§† Micah J. Manary,§†  
Harry B. Gray,§ and Adrian Ponce§† 
 
§Beckman Institute, California Institute of Technology, Pasadena, California 91125, and 
†Planetary Science Section, Jet Propulsion Laboratory, 4800 Oak Grove Drive, Pasadena, 
California 91109 
 
james.p.kirby@jpl.nasa.gov; ponce@caltech.edu; hbgray@caltech.edu  
 
 
 
 
Derivation of Model for Ln(DPA) Binding Affinity. 
 
We start with the equilibrium described in [1], where Ln3+ is any lanthanide, and which 
has the corresponding equilibrium expression written in [2]. 
 
 
  Ln3+  +  DPA2-                          Ln(DPA)+            [1] 
 
 
       [2] 
 
 
We can write the total concentrations of lanthanide and DPA, or CLn and CDPA, as follows 
in equations [3] and [4]. 
 
       [3] 
 
       [4] 
 
These can be rearranged to produce equations [5] and [6]. 
 
       [5] 
 
       [6] 
eq
2
eq
3
eq
a ][DPA][Ln
][Ln(DPA)
K 


eqeq
3
Ln ][Ln(DPA)]Ln[C
 
eqeq
2
DPA ][Ln(DPA)]DPA[C
 
eqLneq
3 ][Ln(DPA)C][Ln  
eqDPAeq
2 ][Ln(DPA)C]DPA[  
Ka
S2 
Substituting equations [5] and [6] into equation [2], we have equation [7]. 
 
 
       [7] 
 
 
Rearranging, we have equation [8]. 
 
       [8] 
 
 
Let us introduce a normalization factor, R, given in equation [9]. 
 
       [9] 
 
 
Substituting equation [6] into equation [9], we have equation [10]. 
 
     [10] 
 
 
Substituting equation [10] into equation [8] and simplifying, we have equation [11]. 
 
     [11] 
 
 
 
Rearranging, we end with equation [12], which has a linear relationship between two 
components dependent on [Ln(DPA)+]eq, CLn and CDPA. 
 
     [12] 
 
 
Thus, a plot of log(CLn – RCDPA) vs log (R/(1 – R)) will produce a linear fit with a slope 
of unity and a y-intercept equal to the logarithm of Ka. 
 
 
 
 
 
 
 
 
 
 
 
)][Ln(DPA))(C][Ln(DPA)(C
][Ln(DPA)
K
eqDPAeqLn
eq
a 


2
eqLneqDPAeqDPALn
eq
a )][Ln(DPA)(C][Ln(DPA)C][Ln(DPA)CC
][Ln(DPA)
K 


eq
2
eq
eq
][(DPA)][Ln(DPA)
][Ln(DPA)
R 


DPA
2
LnDPALn
a CRRCRCC
RK 
   aDPALn KlogRCClogR-1
Rlog 


DPA
eq
C
][Ln(DPA)
R


S3 
 
Figure S1.  Linear fit of log(CTb – RCDPA) vs log (R/(1 – R)) with slope set to unity and y-
intercept corresponding to log Ka. 10.0 nM DPA titrated with TbCl3 in 0.2 M sodium acetate, 
pH 7.4, 24.5°C (λex = 278 nm). 
-2.5
-2
-1.5
-1
-0.5
0
0.5
1
1.5
-9.5 -9 -8.5 -8 -7.5 -7 -6.5 -6
lo
g 
[R
/(1
 - 
R
)]
log (C
Tb
 - RC
DPA
)
y = m0 + m1
ErrorValue
0.0190137.4086m1 
NA0.026028Chisq
NA0.99648R2
S4 
 
 
 
 
 
 
Figure S3.  Thermal ellipsoid plots of the Sm coordination geometry in the Sm(DO2A)(DPA)− ternary 
complex with 50% probability.  (A)  Looking across the complex, with DO2A below and DPA above 
the Sm3+ central ion.  (B)  Looking down the DPA ligand (the N1 of the DPA is obstructing the view of 
the Sm). 
A B
Figure S2.  Thermal ellipsoid plot of the Dy(DO2A)(DPA)− ternary complex with 50% 
probability.  Hydrogens omitted for clarity.
S5 
 
 
 
250 260 270 280 290 300
Wavelength (nm)
N
or
m
al
iz
ed
 E
m
is
si
on
 In
te
ns
ity
, 5
44
 n
m
250 260 270 280 290 300
Wavelength (nm)
N
or
m
al
iz
ed
 A
bs
or
ba
nc
e
Figure S4.  Normalized excitation (A) and absorption (B) spectra of Ln(DO2A)(DPA)- complexes, 
where Ln = Sm (dotted), Eu (dashed), Tb (solid) or Dy (dashed-dotted), at 10.0 μM in 0.1 M Tris, pH 
7.9.  Excitation wavelengths: λSm = 600 nm, λEu = 615 nm, λTb = 544 nm, λDy = 574 nm. 
A B
S6 
Calculation of Quantum Yields and Molar Extinction Coefficients for 
Ln(DO2A)(DPA)- Complexes. 
 
We start with the standard equation for calculation of luminescence quantum yield in [1].  
 
 
  2ST
2
X
XX
STST
XX
STST
ST
X
ST
X
η
η
λI
λI
λA
λA
E
E
Φ
Φ             [1] 
 
where  
StandardST
SampleX
solvent ofindex  Refractive
gth at wavelenlight  excitation ofIntensity I
h  wavelengtexcitation at the AbsorbanceA
intensityemission  ceFluorescenE
yield Quantum










 
 
To fit our data to a linear least-squares regression, we introduce a gradient relationship in 
[2]. 
A
EGrad                 [2] 
 
Substituting equation [2] into equation [1], we end with equation [3]. 
  
  2ST
2
X
XX
STST
ST
X
STX η
η
λI
λI
Grad
GradΦΦ              [3] 
 
Data was plotted as emission intensity against absorbance, and the resulting values of 
GradX and GradST were applied to equation [3] to obtain the quantum yield, with L-
tryptophan as the standard (εExp = 5277.4 M-1cm-1, εTheor = 5502 M-1cm-1).29 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
S7 
Molar extinction coefficients were also calculated for all four ternary complexes and the 
dipicolinate anion by plotting absorbance against concentration. 
 
 
 
 
 
 
Table S1.  Molar extinction coefficients of the Ln(DO2A)(DPA)- complexes (Ln = Sm, Eu, Tb, Dy) 
and the DPA2- anion. 
 
Complex Buffer λabs 
(nm) 
Temp 
(°C) 
pH εExp  
(M-1cm-1) 
Sm(DO2A)(DPA)- 22.0 7.49 4160 ± 10 
Eu(DO2A)(DPA)- 22.1 7.46 3369 ± 24 
Tb(DO2A)(DPA)- 22.0 7.43 2259 ± 10 
Dy(DO2A)(DPA)- 22.1 7.49 3803 ± 2 
DPA2- 
0.1 M Tris 280 
22.3 7.50 2832 ± 21 
 
 
Molar extinction coefficients are all in the same range of 103 M-1cm-1, which is expected 
as all contain the same amount of dipicolinate, the only strongly absorbing species. 
 
Figure S5.  Linear fit of absorbance (λabs = 280 nm) versus concentration for the 
Ln(DO2A)(DPA)- complexes (Ln = Sm, Eu, Tb, Dy) in 0.1 M Tris buffer, pH 7.5. 
y = 2258.8x + 0.0004
R2 = 0.9972
y = 3369.4x + 0.0014
R2 = 0.9951
y = 3803.2x - 0.0003
R2 = 0.9992
y = 4160.3x - 0.0002
R2 = 0.9986
y = 2831.8x - 0.0001
R2 = 0.9975
0
0.01
0.02
0.03
0.04
0.05
0.06
0.07
0.0E+00 2.0E-06 4.0E-06 6.0E-06 8.0E-06 1.0E-05 1.2E-05 1.4E-05 1.6E-05
Concentration (M)
A
bs
or
ba
nc
e 
at
 2
80
 n
m
Tb(DO2A)(DPA)
Eu(DO2A)(DPA)
Dy(DO2A)(DPA)
Sm(DO2A)(DPA)
DPA
S8 
 
Table S2.  Stability of the Tb(DO2A)(DPA)- complex over time. 
 
Eq. Time pH log Ka’ 
8 days 7.5  9.25 ± 0.13§ 
5 months 7.4 9.30 ± 0.19 
11 months 7.5 9.12 ± 0.24 
 § Previous work.27 
 
 
S9 
 
 
 
Figure S6.  Emission spectra of various terbium complexes, 10.0 μM in 0.2 M sodium acetate, pH 
7.4 (λex = 278 nm), showing characteristic splitting as a result of changes in the symmetry of the 
Tb3+ coordination sphere. 
450 500 550 600 650
Wavelength (nm)
N
or
m
al
iz
ed
 E
m
is
si
on
 In
te
ns
ity
Tb(DPA)+·6H2O
Tb(DPA)33- 
Tb(DO2A)(DPA)-
J = 6 
5D4 → 7FJJ = 5 
J = 4 
J = 3 
S10 
 
 
550 600 650 700 750
Wavelength (nm)
N
or
m
al
iz
ed
 E
m
is
si
on
 In
te
ns
ity
Figure S7.  Emission spectra of europium complexes, 10.0 μM in 0.2 M sodium acetate, pH 7.4 
(λex = 278 nm). 
Eu(DPA)+·6H2O
Eu(DPA)33- 
Eu(DO2A)(DPA)-
5D0 → 7FJ 
J = 0 
J = 1 
J = 2 
J = 3 
J = 4 
S11 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
525 575 625 675 725
Wavelength (nm)
N
or
m
al
iz
ed
 E
m
is
si
on
 In
te
ns
ity
Figure S8.  Emission spectra of samarium complexes, 10.0 μM in 0.2 M sodium acetate, pH 7.4 
(λex = 278 nm). 
Sm(DPA)+·6H2O
Sm(DPA)33-
Sm(DO2A)(DPA)-
4G5/2 → 6HJ
J = 5/2 
J = 7/2 
J = 9/2 
J = 11/2, 13/2 
S12 
 
 
 
0.0E+00
5.0E+05
1.0E+06
1.5E+06
2.0E+06
2.5E+06
3.0E+06
3.5E+06
4.0E+06
570 575 580 585 590 595 600
Wavelength (nm)
In
te
ns
ity
, S
/R
 (c
ps
)
Tb(DPA)
Tb(DPA)3
Tb(DO2A)(DPA)
Figure S9.  Emission spectra of the three terbium dipicolinate complexes, all 10.0 μM in 0.1 M 
MOPS buffer, pH 7.4. 
S13 
 
 
Figure S11.  Emission intensity variation of 0.1 μM Tb(DO2A)(DPA)- complex (gray bars) or 
Tb(DPA)+ complex (white bars) with the addition of 0.01 M ion, pH 5.6.  Normalized integrated 
emission intensity, 530 – 560 nm; λex = 278 nm. 
0.0
0.2
0.4
0.6
0.8
1.0
1.2
Co
ntr
ol
Ma
gn
es
ium
Ca
lciu
m
Lit
hiu
m
So
diu
m
Po
tas
siu
m
Am
mo
niu
m
Ce
siu
m
Ac
eta
te
Nit
rat
e
Flu
ori
de
Br
om
ide
Iod
ide
Ca
rbo
na
te
Su
lfa
te
Ph
os
ph
ate
Cit
rat
e
N
or
m
al
iz
ed
 E
m
is
si
on
 In
te
ns
ity
Figure S10.  Emission intensity variation of 0.1 μM Tb(DO2A)(DPA)- complex (gray bars) or 
Tb(DPA)+ complex (white bars) with the addition of 0.1 M ion, pH 6.6.  Normalized integrated 
emission intensity, 530 – 560 nm; λex = 278 nm. 
0.0
0.2
0.4
0.6
0.8
1.0
Co
ntr
ol
Ma
gn
es
ium
Ca
lciu
m
Lit
hiu
m
So
diu
m
Po
tas
siu
m
Am
mo
niu
m
Ce
siu
m
Ac
eta
te
Nit
rat
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Flu
ori
de
Br
om
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Iod
ide
Ca
rbo
na
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Su
lfa
te
Ph
os
ph
ate
Cit
rat
e
N
or
m
al
iz
ed
 E
m
is
si
on
 In
te
ns
ity
S14 
 
 
Figure S13.  Emission intensity variation of 0.1 μM Tb(DO2A)(DPA)- complex (gray bars) or 
Tb(DPA)+ complex (white bars) with the addition of 0.1 mM ion, pH 5.0.  Normalized integrated 
emission intensity, 530 – 560 nm; λex = 278 nm. 
0.0
0.2
0.4
0.6
0.8
1.0
Co
ntr
ol
Ma
gn
es
ium
Ca
lciu
m
Lit
hiu
m
So
diu
m
Po
tas
siu
m
Am
mo
niu
m
Ce
siu
m
Ac
eta
te
Nit
rat
e
Flu
ori
de
Br
om
ide
Iod
ide
Ca
rbo
na
te
Su
lfa
te
Ph
os
ph
ate
Cit
rat
e
N
or
m
al
iz
ed
 E
m
is
si
on
 In
te
ns
ity
Figure S12.  Emission intensity variation of 0.1 μM Tb(DO2A)(DPA)- complex (gray bars) or 
Tb(DPA)+ complex (white bars) with the addition of 1.0 mM ion, pH 5.3.  Normalized integrated 
emission intensity, 530 – 560 nm; λex = 278 nm. 
0.0
0.2
0.4
0.6
0.8
1.0
Co
ntr
ol
Ma
gn
es
ium
Ca
lciu
m
Lit
hiu
m
So
diu
m
Po
tas
siu
m
Am
mo
niu
m
Ce
siu
m
Ac
eta
te
Nit
rat
e
Flu
ori
de
Br
om
ide
Iod
ide
Ca
rbo
na
te
Su
lfa
te
Ph
os
ph
ate
Cit
rat
e
N
or
m
al
iz
ed
 E
m
is
si
on
 In
te
ns
ity
S15 
 
 
 
 
 
 
 
Figure S14.  Ion competition experiment of 0.1 μM Tb(DO2A)(DPA)- titrated with phosphate (♦), 
sulfate (■), potassium (▲) or carbonate (●) over a concentration range from 1.0 nM to 100 mM, 
pH 7.5 (0.1 M MOPS).  Carbonate appears to be the only ion that competes, and only at very 
high concentrations (1:105 [Tb(DO2A)(DPA)-] : [CO32-]). 
0
0.2
0.4
0.6
0.8
1
-10 -9 -8 -7 -6 -5 -4 -3 -2 -1
log [Ion]
N
or
m
al
iz
ed
 In
t. 
In
te
ns
ity
, 5
30
 - 
56
0 
nm
S16 
 
 
 
Figure S15.  Plot of ln Ka’ versus 1/T for Tb(DO2A)(DPA)- (blue) and Eu(DO2A)(DPA)- (green), 
200mM NaAc, pH 7.4.  Calculations of enthalpy and entropy for each complex give the following: 
ΔHTb = -1960 J, ΔSTb = 108 J·K-1. ΔHEu = -2480 J, ΔSEu = 76 J·K-1. 
y = 2356.3x + 12.948
R2 = 0.5793
y = 2984x + 9.1694
R2 = 0.9221
17.0
17.5
18.0
18.5
19.0
19.5
20.0
20.5
21.0
21.5
22.0
3.0E-03 3.1E-03 3.2E-03 3.3E-03 3.4E-03 3.5E-03 3.6E-03
1/T (K-1)
ln
 K
a '
Tb
Eu
S17 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Figure S16.  Time course of addition of 1.0 μM DPA to 1.0 μM Tb(DO2A)+ in 0.1 M MOPS buffer 
(pH 7.4) and 0.1 M CAPS buffer (pH 10.4).  Emission intensity was monitored at 544 nm (λex = 
278 nm) before, during and after DPA addition (T = 0).  Complete Tb(DO2A)(DPA)- formation was 
observed after approx. 3 sec at pH 7.4, 15 sec at pH 10.4. 
-20 -10 0 10 20 30 40 50 60 70
Time (s)
N
or
m
al
iz
ed
 In
te
ns
ity
 a
t 5
44
 n
m
 l
pH 7.4
pH 10.4
S18 
Calculation of Signal-to-Noise Ratio for Bacterial Spore Detection Study. 
 
In spectroscopy, the signal-to-noise (S/N) ratio is defined as the ratio of the amplitude of 
the desired signal to the amplitude of noise signals.  To calculate the S/N ratio for our 
bacterial spore detection experiment, we use the most intense peak of the Tb emission 
spectrum (λem = 544 nm).  Signal amplitude was calculated by subtracting the maximum 
observed intensity in the range of 530 – 560 nm from the minimum observed intensity. 
 
 
 
This was performed both for the sample, which contained the lysed bacterial spores and 
either the Tb3+ or Tb(DO2A)+ complex, and for the analogous control, containing either 
Tb3+ or Tb(DO2A)+ alone.  The ratio of these two amplitudes produced the S/N ratio: 
 
ControlControl
SampleSample
MinMax
MinMax
N
S

  
 
The calculated S/N ratios for each of the five trials were averaged to produce the final 
values for the Tb3+ and Tb(DO2A)+ complexes (see Table S3). 
 
 
 
Figure S17.  Example of signal and noise amplitude measurements from emission 
spectrum, 530 – 560 nm. 
S19 
Table S3.  Calculated S/N ratios for the bacterial spore detection study 
 
Trial Tb3+ Tb(DO2A)+ 
1 12.8 41.1 
2 14.2 38.8 
3 11.6 57.8 
4 15.8 37.1 
5 15.9 51.2 
Avg 14.1 ± 1.9 45.2 ± 8.9 
 
 
 
 
 


Detection of bacterial spores with lanthanide-macrocycle binary complexes

http://authors.library.caltech.edu/14958/1/Cable2009p5146J_Am_Chem_Soc.pdf

Detection of bacterial spores with lanthanide-macrocycle binary complexes

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