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DNA Binding Behavior, Sensor Studies, Antimicrobial, Photocleavage and In vitro Cytotoxicity of Synthesized Ru(II) Complexes with Assorted Intercalating Polypyridyl Ligands.
J Fluoresc
DOI 10.1007/s10895-012-1090-9
ORIGINAL PAPER
Spectroscopic Study of Porphyrin-Caffeine Interactions
Magdalena Makarska-Bialokoz
Received: 22 March 2012 / Accepted: 20 June 2012
# The Author(s) 2012. This article is published with open access at Springerlink.com
Abstract The association between water-soluble porphyrins: 4,4′,4″,4‴-(21H,23H-porphine-5,10,15,20-tetrayl)tetrakis-(benzoic acid) (H 2 TCPP), 5,10,15,20-tetrakis(4sulfonatophenyl)-21 H,23 H-porphine (H 2 TPPS 4 ),
5,10,15,20-tetrakis[4-(trimethylammonio)phenyl]-21 H,23
H-porphine tetra-p-tosylate (H2TTMePP), 5,10,15,20-tetrakis(1-methyl-4-pyridyl)-21H,23H-porphine tetra-p-tosylate
(H2TMePyP), the Cu(II) complexes of H2TTMePP and
H2TMePyP, as well as chlorophyll a with caffeine (1,3,7trimethylxanthine) has been studied analysing their absorption and emission spectra in aqueous (or acetone in case of
chlorophyll a) solution. During the titration by caffeine the
porphyrins absorption spectra undergo the evolution – the
bathochromic effect can be observed as well as the hypochromicity of the Soret maximum. The association constants
were calculated using curve-fitting procedure (KAC of the
order of magnitude of 103 mol-1). Whereas the emission
spectra point at the presence of the fluorescence quenching
effect testifying for the partial inactivation of the porphyrin
molecule. The fluorescence quenching constants were calculated from Stern-Volmer plots. The results obtained show
that caffeine can interact with water-soluble porphyrins and
through formation of stacking complexes is able to quench
their ability to emission.
Keywords Caffeine . Porphyrin . Chlorophyll .
Fluorescence quenching . Non-linear Stern-Volmer plots
M. Makarska-Bialokoz (*)
Department of Inorganic Chemistry,
Maria Curie-Sklodowska University,
M. C. Sklodowska Sq. 2,
20-031, Lublin, Poland
e-mail: makarska@hektor.umcs.lublin.pl
Introduction
Caffeine (1,3,7-trimethylxanthine) is one of the most popular stimulants and an ingredient of many anaesthetic, antifever or dietary medicines. This compound is present as well
in various plants where it acts as a natural pesticide, paralysing and killing insects that try to feed on the plant.
Naturally occurring xanthines, like caffeine, are often included in the binding interceptor group [1]. It has been
previously reported that methylxanthines are able to protect
cells against the cytostatic and cytotoxic effects of some
aromatic compounds by reduction of their mutagenic activity [2, 3]. Caffeine and other methylxanthines can form
stacking complexes with several aromatic compounds, like
anticancer drugs [2, 4], fluorescence dyes [5–9], mutagens
[10, 11], neurotoxins [12, 13] and others [14, 15]. The
authors of papers cited above assumed that heteroassociation of methylxanthines with these compounds may
diminish their biological activity. To reveal a possible mechanism that demonstrates the protective abilities of caffeine
by stacking up and blocking the detrimental activity of
aromatic mutagens and carcinogens UV–VIS spectroscopy
and other techniques have been used [3].
In all products containing caffeine this compound occurs
in the form of solution or water mixture. The gigantic
consumption of caffeine means simultaneously the similar
order of caffeine sewage production. The environment contamination caused by caffeine and its metabolites influences
also the condition of water plant and animal organisms.
Caffeine exposure induces as well early senescence in land
plants and retards seedling growth [16]. The studies described in literature testify for the inhibiting influence of
caffeine on the photosynthesis process of organisms leading
to the decreasing of chlorophyll activity [16, 17]. It was
found that the changes in chlorophyll fluorescence can be a
cause of photosynthesis disturbance [18]. Therefore
�J Fluoresc
chlorophyll can be recognized not only as an indicator of the
environment degradation due to contamination with heavy
metals [19], but also as a sensitive biomarker of plant stress,
taking into consideration that any kind of plant stress can
affect plant growth as well as the process of photosynthesis.
Although caffeine is usually well-metabolized by human
organism, its presence in surface water is considerable [20],
particularly in the vicinity of inhabited areas, where this
compound is delivered to the water environment in a continuous manner. It was found that the caffeine content is
connected as well with the presence of human sewage in
surface water. Sauve and co-workers proved that caffeine
concentrations are relatively well correlated to cefal coliforms and could be potentially used as a chemical indicator
of the level of contamination by sanitary sources and thereby could play a role of an anthropogenic marker [20, 21].
Therefore a precise detection of caffeine included in environmental samples can be significant for instance in monitoring of places with crude wastes thrown away out-ofcontrol or drugs of abuse excreted unmetabolized or as
metabolites to the sewage system [22].
Studies described in this paper concern the spectroscopic
analysis of interactions between biologically important macromolecules. The primary objective of presented research
was to specify the mechanism of interactions of the chosen
compounds from the class of water-soluble porphyrins with
caffeine and verify as well their usefulness as chemical
indicators of caffeine. The water-soluble porphyrins are the
compounds with the specific spectroscopic and redox properties, as well as the ability to electron transfer, very sensitive to the subtle changes of pH, porphyrins and ligands
concentration or form of complexing with metal ions proceeding in a reaction environment, what can be utilized
among other things in their interactions with DNA
[23–27], nucleic bases [28, M. Makarska-Bialokoz - unpublished results] and, what is equally important, in biomimetic
catalysis [29–31] as well as in monitoring of the porphyrins
interactions with different kinds of toxic substances [32, 33].
The secondary objective was to compare the behaviour
of chlorophyll a (the porphyrin compound which is not
soluble in water), during interaction with caffeine, to the
results obtained for water-soluble porphyrins. To determine the caffeine - porphyrins relations the absorption
and emission spectra evolution was observed during the
titration by caffeine a series of water-soluble synthetic
porphyrins: 5,10,15,20-tetrakis[4-(trimethylammonio)phenyl]porphine (H 2 TTMePP), 5,10,15,20-tetrakis(1methyl-4-pyridyl)porphine (H2TMePyP), their complexes
with Cu(II) (CuTTMePP and CuTMePyP), 4,4′,4″’,4‴(21 H,23 H-porphine-5,10,15,20-tetrayl)tetrakis-(benzoic
acid) (H2TCPP), 5,10,15,20-tetrakis(4-sulfonatophenyl)porphine) (H2TPPS4) and chlorophyll a (commercial
reagent) (Fig. 1).
This paper presents, to the best of my knowledge for the
first time, complex spectroscopic interaction analysis of
water-soluble porphyrins and their copper (II) complexes
with water solution of caffeine [M. Makarska-Bialokoz –
personal communications: 2nd International Conference on
Multifunctional, Hybrid and Nanomaterials, HYMA, Strasbourg, France (06–10.03.2011)]. The association constants
as well as the fluorescence quenching constants calculated
for the examined systems could be recognized as well as the
novelty.
Experimental
Reagents
Caffeine (1,3,7-trimethylxanthine) and the porphyrins:
4,4′,4″,4‴-(21H,23H-porphine-5,10,15,20-tetrayl)tetrakis(benzoic acid) (H2TCPP, lg ε05.47, 415 nm); 5,10,15,20tetrakis(4-sulfonatophenyl)-21H,23H-porphine (H2TPPS4, lg
ε05.25, 413 nm); 5,10,15,20-tetrakis[4-(trimethylammonio)phenyl]-21H,23H-porphine tetra-p-tosylate (H2TTMePP, lg
ε05.59, 412 nm) and 5,10,15,20-tetrakis(1-methyl-4-pyridyl)-21H,23H-porphine tetra-p-tosylate (H2TMePyP, lg ε0
5.32, 421 nm) were purchased in ALDRICH and used without
any additional purification, whereas copper (II) complexes of
H2TTMePP and H2TMePyP (CuTTMePP, lg ε05.49, 412 nm
and CuTMePyP, lg ε05.34, 424 nm) were synthesized by the
modification of the method described earlier in literature
[34–36]. Chlorophyll a (lg ε05.13–5.23 for 428 nm and
5.05–5.14 for 660 nm) was also purchased in
ALDRICH, while acetone in POCh S.A. Polskie Odczynniki
Chemiczne.
Measurements
The titration experiments were carried out using a
10−3 mol dm−3 stock solution of ligand (caffeine). The
porphyrin solutions were freshly prepared in water (chlorophyll a solution in acetone) at the concentration range about
10−7 mol dm−3 to prepare the starting solution with the
porphyrin absorbance value equals approximately 0.1. The
initial volume of the porphyrin solutions used was 2 cm3.
The volumes of the stock caffeine solution added at each
step during titration of a porphyrin were as follows: 0,
0.005, 0.02, 0.03, 0.05, 0.1, 0.1, 0.2, 0.2, 0.2, 0.2 and
0.3 cm 3 (final volume of stock caffeine solution was
1.405 cm 3 ; final volume of solution in a cell was
3.405 cm 3 ). The porphyrin concentration in case of
H2TTMePP and chlorophyll a was changing in the range
3.27 – 1.92 10-7 mol dm−3 and 7.34 – 4.31 10-7 mol dm−3,
respectively. The final concentration of caffeine in the mixture was 4.13 10−4 mol dm−3.
�J Fluoresc
Fig. 1 The molecular structures of (a) caffeine(1,3,7-trimethylxanthine), (b) chlorophyll a and (c) H2TTMePP (5,10,15,20-tetrakis[4(trimethylammonio)phenyl]-21H,23H-porphine)
Absorption spectra were recorded on JASCO V-660 spectrophotometer, using 1 cm Hellma quartz cells to obtain spectra between 350 and 700 nm at the temperature of 21 °C.
Emission spectra were recorded on JASCO FP-6300 spectrofluorometer. The database program Sigma Plot (version 9.0)
(Jandel Corp.) was used in the manipulation and plotting of the
data.
Calculation of the Association Constants for Porphyrin Caffeine Systems
To calculate the association (binding) constants the absorbance values in the Soret maximum were employed, because of higher comparing to Q band values of molar
absorbance index, which permit to carry out the measurements at porphyrin concentration of the order of 10−7, what
minimizes the dimerization process. The calculations were
done using the Beck equation [37], which could be applied
to obtained binding constants only on condition that the
concentration of titrant is at least 100 times higher than the
concentration of the compound examined.
For the determination of association constants of porphyrin – ligand (caffeine) complexes, according to reaction:
L
L
P þ L !PL !PðLÞ
2 þ ::: !PðLÞn
ð1Þ
the equilibrium constant Kn can be written:
�
�
PðLÞn
�
Kn ¼ �
PðLÞn�1 ½ L�
ð2Þ
To calculate the final results the equation based on Bjerrum function modified by Beck [37] was applied:
A¼
"0 þ "1 K1 ½ L� þ "2 K1 K2 ½ L�2 þ ::: þ "n K1 K2 :::Kn ½ L�n
1 þ K1 ½ L� þ K1 K2 ½ L�2 þ ::: þ K1 K2 :::Kn ½ L�n
½ P�
ð3Þ
where A is the absorbance; ε0, the molar absorbance index
for starting porphyrin; ε1 and K1, ε2 and K2, …, etc. are
molar absorbance indexes and gradual binding constants for
complexes with the stoichiometry 1:1, 1:2, …, etc., respectively; [L] and [P] stand for the analytical concentration of
ligand (caffeine) and porphyrin.
Taking into consideration the 1:1 model of complex
formation, the values of K 1 for all the porphyrins
examined were determined by fitting the experimental
data to Eq. (4), using the non-linear fitting procedure
based on Marquardt–Levenberg algorithm (program
Sigma Plot).
�J Fluoresc
A¼
"0 þ "1 K1 ½ L�
½ P�
1 þ K1 ½ L�
ð4Þ
The fitting procedure realized for 1:2 model did not make
any physical sense.
Calculation of the Fluorescence Quenching Constants
for Porphyrin - Caffeine Systems
Quenching of fluorescence is usually described by the classic Stern-Volmer equation:
F0
¼ 1 þ KSV ½Q�
F
ð5Þ
where F0 and F are the fluorescence intensities in the absence and presence of quencher, respectively; [Q] is the
concentration of quencher, KSV is the Stern-Volmer quenching constant.
According to the experimental data, suggesting the presence of stacking interactions between caffeine and porphyrin systems, it was decided to determine the fluorescence
quenching constants, taking into consideration primarily the
process of static quenching [38]. To calculate the fluorescence quenching constants for all the systems examined the
equation was applied
F0
¼ 1 þ KS ½Q�
F
ð6Þ
where KS denotes the static quenching constant.
To calculate KS the experimental data for each quencher
concentration were fitted to Eq. (6) using the non-linear
fitting procedure based on Marquardt–Levenberg algorithm
(program Sigma Plot).
When the static quenching predominates, as in all probability in case of presented studies, a number of binding
sites can be calculated
lg
F0 � F
¼ lg KAC þ n lg½Q�
F
ð7Þ
where KAC is binding (association) constant, n is a number
of binding sites, [Q] is the final concentration of quencher
(caffeine), F0 and F are the fluorescence intensities for the
porphyrin system in the absence and presence of quencher,
respectively [39].
Results and Discussion
Analysis of Porphyrin - Caffeine Systems: UV–VIS
and Fluorescence Spectra
The water-soluble porphyrin solutions were titrated by water
in dilution experiment. All the systems examined behaved
similarly and fulfilled a condition of the linearity of
Beer-Lambert law. To avoid the concentration fluorescence
quenching effect on emission spectra of porphyrins the
measurements were carried out using the initial concentration of these compounds with the porphyrin absorbance
values equal approximately 0.1. The phenomenon of concentration fluorescence quenching is known in chemistry
since a long time [40] and connected with the fluorophore
excess in a solution and with its diversified possibility to
aggregation [41, 42], as well as with the polarity of examined system. The concentration quenching is particularly
common for large aromatic molecules such as porphyrins,
due to their ability to formation of dimers or bigger aggregates [43, 44], what can lead to partial or complete fluorescence decay, as a result of energy dissipation as well as reabsorption of emitted light.
The evolution of absorption and emission spectra during
the interactions between caffeine and a series of synthetic
water-soluble porphyrins (H 2 TMePyP, CuTMePyP,
H2TTMePP, CuTTMePP, H2TCPP, H2TPPS4) was recorded.
In absorption spectra of H2TTMePP porphyrin the hypochromicity of the peak in Soret band and a shift towards the
infrared (bathochromic effect, λmax 0412–417 nm) can be
observed (Fig. 2). In Q band the similar changes proceed,
apparent particularly for IV band component (λmax 0514–
517 nm). For all the systems examined the dependence of
absorbance vs. molar concentration of porphyrin shows the
deviations from linearity confirming the existence of porphyrin – caffeine interactions.
In emission spectra, which undergo the bathochromic effect as absorption spectra, the decrease of peak maximum is
observed, what testifies for the interactions with caffeine
influencing the partial inactivation of the porphyrin and faster
decay of its luminescence properties. In the same manner react
H2TTMePP (Fig. 3), H2TCPP and H2TPPS4 porphyrins.
While H2TMePyP is the only porphyrin, which in these
experimental conditions is shifted towards the ultraviolet and
shows the initial increase of the emission intensity.
Whereas the metalloporphyrins CuTTMePP and CuTMePyP
present a different behaviour. The bathochromic shift of Soret
band in absorption spectrum points at the interactions with
caffeine, stronger in case of CuTTMePP. While the value
of the emission intensity observed for these compounds
is minimal, what testifies that the copper ions extinguish
luminescence properties of the porphyrin complex. Such
behaviour is typical for hypsochromic spectra of metalloporphyrins with Cu (II) ions [38, 45, 46]. The emission intensity of CuTTMePP complex is slightly higher,
what is connected with a different structure of this
complex. The big substituents of H2TTMePP porphyrin
do not allow for entire hiding of Cu2+ ions in the
porphyrin cave, forming the steric hindrance for the
metal ions [47].
�J Fluoresc
Fig. 2 Evolution of
H2TTMePP absorption
spectrum during titration by
caffeine. The dependence of
absorbance versus porphyrin
concentration for the process
presented. The concentrations
of the porphyrin and caffeine in
solution changed in the range
3.27 – 1.92 (× 10-7 mol dm-3)
and 0–4.13×10-4 mol dm-3,
respectively
Acetone solution of chlorophyll a was titrated both by
acetone and water in order to separate the influence of these
solvents on absorption and emission spectra of this compound. The slight deviations from Beer-Lambert law
appearing in absorption spectrum of chlorophyll a (Fig. 4)
can testify either for the minimal interactions with caffeine
or for the time dependence occurring during this reaction or,
what seems the most likely, for the different comparing to
other porphyrins mechanism of interactions.
Both pure water and water solution of caffeine quench
the fluorescence of chlorophyll a, as arises from the titration
data (Fig. 5). The different mechanism of fluorescence
quenching in case of this compound is probably the consequence of its structure, containing the phytol chain, which
can hinder to some extent the binding of caffeine, as well as
Fig. 3 Evolution of
H2TTMePP emission spectrum
during titration by caffeine. The
dependence of fluorescence
intensity versus porphyrin
concentration for the process
presented. All the
concentrations as in Fig. 2
the form of a molecule, changing with the polarity of titrated
solution. In acetone solution chlorophyll appears in monomeric form, due to interaction between central Mg in chlorophyll molecule, which acts as electron acceptor and
carbonyl group in acetone molecule, which acts as electron
donor [48]. Titration by water solution of caffeine increases
the polarity of reaction environment, leading to formation of
bigger aggregated molecules. Addition of water to acetone
solution causes quenching of chlorophyll a fluorescence,
what does not exclude the simultaneous interaction with
caffeine. It was found that monomeric form of chlorophyll
is less stable than dimeric (aggregated) form. In chlorophyll
aggregates one chlorophyll may act as an electron donor and
the other as electron acceptor via its central magnesium [48].
Therefore the obtained results point in this case at more than
�J Fluoresc
Fig. 4 Evolution of
chlorophyll a absorption
spectrum during titration by
caffeine. The dependence of
absorbance versus chlorophyll a
concentration for the process
presented. The concentrations
of chlorophyll a and caffeine in
solution changed in the range
7.34 – 4.31 (× 10-7 mol dm-3)
and 0–4.13×10-4 mol dm-3,
respectively
one mechanism of quenching and, possibly, more than one
quenching centres [49].
The Association Process in Porphyrin - Caffeine Systems
The values of association (binding) constants calculated for all
the systems examined are presented in Table 1. The results
point unequivocally at formation of associated systems between porphyrin compounds and caffeine. Hypochromic and
bathochromic effects, occurring during the experiments, indicate that, upon the addition of caffeine to porphyrin solution, a
new absorbing component appears in the mixture. Since both
caffeine and porphyrin posses an aromatic structure, therefore
they are capable of stacking complexes formation [1], founded
on the interceptor molecule hypothesis postulated by Hartman
and Shankel [50], which explains the existence of stacking
Fig. 5 Evolution of
chlorophyll a emission
spectrum during titration by
caffeine. The dependence of
fluorescence intensity versus
chlorophyll a concentration for
titration by caffeine, water and
acetone. All the concentrations
as in Fig. 4
interactions between the interceptor (flat ring system) and
intercalator (polycyclic molecule).
In discussed experiments higher values of association constants were obtained for the copper complexes comparing to
free-base porphyrins, what have been already presented [51].
The values of KAC for the compounds with 4-(trimethylammonio)phenyl groups (both free-base porphyrin and its copper
complex) are higher comparing to the compounds with 1methyl-4-pyridyl groups. It has been shown as well that the
interactions of H2TTMePP with nucleic bases are much stronger than interactions of H2TMePyP what is most likely
connected with the kind and the size of substituent porphyrin
groups partaking in the process of stacking [M.
Makarska-Bialokoz - unpublished results]. The charge of
porphyrin substituent groups is also significant for the
porphyrin – caffeine interactions. The cationic porphyrins
�J Fluoresc
Table 1 The binding (association) constants of associated
molecules [mol-1] formed between porphyrins or their copper
complexes and caffeine (error
limits: ± 5 %)
a
Error limits higher than 5 %
binding constant
[mol-1]×103
number of
binding sites (n)
5.0
8.39
1.12
5.0
3.0
12.06
2.90a
1.80
1.31
425.0
415.0
1.0
4.0
10.61
19.97
1.65
1.29
H2TPPS4
414.0
4.0
1.74a
chlorophyll a
430.0
1.0
11.15a
1.00
1.12
porphyrin compound
absorbance
maximum at
Soret band [nm]
Soret band shift
during titration
with caffeine [nm]
H2TTMePP
412.0
CuTTMePP
H2TMePyP
412.0
422.0
CuTMePyP
H2TCPP
seem to react stronger than the anionic ones (H2TPPS4).
Nevertheless in case of H2TCPP porphyrin the highest value
of KAC is observed. Such result can be attributed to the
different reaction environment - H2TCPP, which is hardly
soluble in pure water, was dissolved in 0.01 mol dm−3 NaOH
solution.
On the grounds of porphyrin – caffeine interactions analysis it was found that porphyrin compounds can react with
caffeine molecule both by metal ions and hydrogen atoms
presented in a porphyrin cave in case of complexes and freebase porphyrins, respectively, as well as by charged substituent groups. Caffeine interacts with porphyrins by a hydrogen
bond as well as the interactions of an endocyclic nitrogen
atom (N9) with a metal ion from a porphyrin cave. The
confirmation of this postulate was presented by Fiammengo
[51], describing the caffeine interactions with the system of
conjugated with peptides zinc metalloporphyrin. The hydrophobic and hydrogen bonds interactions were as well the
predominant intermolecular forces to stabilize the complex
of caffeine with hemoglobin [39] and human serum albumin
[52, 53] and the complex of amine with chlorophyll [54].
However, the complexity of chlorophyll molecule can lead
to more composite interactions and formation of a system of
different type, or even more than one system.
It should be considered that the structure of each porphyrin
implies its ability to reach the excited state as well as the
degree of the ring protonation process, what influences the
manner of interaction with caffeine. Therefore the differences
in the values of association constants are the consequence of
the spatial structure of particular porphyrin compounds used
in described experiments. Both the size and the charge of
groups on the periphery of porphyrins as well as the type of
porphyrin (free-base porphyrin or metalloporphyrin) and the
axial-ligation of metalloporphyrins determine the position and
a number of binding sites [47] (Table 1). Caffeine is known to
dimerize or self-aggregate in aqueous solutions, but the association constants are very small (5–8 mol−1) and, therefore, do
not affect the binding process [51]. At caffeine concentrations
used in the experiments presented in this paper
(10−4 mol dm−3) caffeine exists in the form of monomer [55].
The Fluorescence Quenching Process in Porphyrin - Caffeine
Systems
Formation of associated complexes, demonstrated by the
calculated association constants KAC, confirms simultaneously the existence of static fluorescence quenching process in the porphyrin – caffeine system. Static quenching is
often observed in case of stacking interactions between the
numerous fluorophores and quenchers, particularly from the
group of purine and pyrimidine nucleotides or related compounds [38]. It was already proved that caffeine could bind
strongly with proteins (hemoglobin, albumin, lysozyme)
[39, 53, 56, 57] and other systems at molar ratio 1:1 and a
reaction is a single static quenching process. Formation of
stacking complexes points unequivocally at static quenching
proceeding in the discussed experiments. The values of
fluorescence quenching constants calculated for all the systems examined are presented in Table 2.
Table. 2 The fluorescence quenching constants of associated molecules [mol-1] formed between porphyrins or their copper complexes
and caffeine (error limits: ± 5 %)
emission intensity
shift during titration
with caffeine [nm]
fluorescence
quenching
constant
[mol-1]×103
porphyrin
compound
emission
intensity
maximum
[nm]
H2TTMePP
639.5
3.0
4.36
CuTTMePP
H2TMePyP
CuTMePyP
H2TCPP
H2TPPS4
chlorophyll a
639.0
650.0
635.5
642.5
640.5
666.5
—b
2.0a
—b
3.5
3.5
4.0
—c
—c
—c
2.90
2.05
4.17d
a
hypsochromic shift
b
bathochromic shift (values of peak maximum on the level of
background)
c
absence of quenching
d
quenching by water (predominantly)
�J Fluoresc
The values of determined KS confirm the statement that
the extent of quenching depends on the structure and physicochemical properties of the fluorophore. The positive values of KS constants were obtained only for H2TTMePP,
chlorophyll a, H 2 TCPP and H 2 TPPS 4 . However, the
quenching of chlorophyll a could be attributed both to water
and caffeine. The obtained results indicate most likely the
existence of at least two simultaneous processes, difficult to
separate, proceeding in the system: (a) dilution of acetone
solution of chlorophyll a by water, connected both with the
aggregation process and quenching activity of water, as well
as (b) quenching of chlorophyll a fluorescence intensity by
caffeine, resulting from the formation of associated complexes. In the event of CuTTMePP and CuTMePyP complexes only the inconsiderable emission can be observed
which could be attributed to the difference in their molecular
geometry and lack of charge transfer state in molecules [58].
In case of H2TMePyP porphyrin initially an increase of
fluorescence is observed and subsequently the slight decrease of emission, what is most likely the consequence of
its molecular structure.
The Stern-Volmer plots would be linear within certain
concentration if the quenching type is single static [39].
Then the values of KS should correspond to the values of
KAC [38]. If the quenching type is combined (both static and
dynamic), the Stern-Volmer plot is an upward curvature,
what can be observed in case of presented results (Fig. 6).
On the other hand the values of calculated fluorescence
quenching constants are predominantly lower comparing
to KAC values and too large to be due to collisional (dynamic) quenching, what confirms simultaneously that caffeine
Fig. 6 Stern-Volmer plots for
all the porphyrin compounds
examined during titration by
caffeine
must be bound to porphyrin. Therefore the observed
quenching process can not be elucidated by the simple static
or dynamic quenching process, or combination of them.
The emission data show that the fluorescence intensity of
examined porphyrins decreases with the increasing concentration of caffeine, resulting in a bathochromic shift of the
peak in case of majority of porphyrins and in a hypsochromic shift as well as a slight change of the peak shape in case
of H2TMePyP porphyrin. It was found that some quenchers
are known to bind to protein and induce conformational
changes [38]. The change of a molecule shape causes not
only the decrease of emission peak, but also its shift. Such
behaviour of quenched compounds, observed in presented
experiments, confirms as well the static quenching
mechanism.
Non-linear Stern-Volmer plots with an inflexion point
at the caffeine concentration equals approximately 2.0 –
2.5 10−4 mol dm−3 are characteristic of all quenched by
caffeine porphyrins. Similar Stern-Volmer plots, composed of two line segments, were presented by Wang
[49]. Such type of plot can indicate that the interaction
mechanism becomes more complex, what can point at
the presence of specific binding interactions, connected
with more than one form of fluorophore, with at least
one form undergoing the quenching process, or more
than one biding site in the neighbourhood of the fluorophore. To sum up, all the results show that in presented systems there are obviously characters of static
quenching, connected with the formation of a groundstate complexes with caffeine, accompanied simultaneously by the additional specific binding interactions.
�J Fluoresc
Conclusions
1. Bathochromic and hypochromic shift of Soret band maximum in absorption spectra and calculation results discussed
in this paper indicate the presence of direct stacking interactions between caffeine and all porphyrins examined. For
all tested compounds increasing concentration of porphyrin caffeine stacking aggregates is associated with the decline in
the concentration of the free active form of porphyrin in the
mixture. Calculated association constants values are in good
agreement with KAC values determined previously for several
aromatic compound - caffeine systems [1, 4, 5, 8].
2. Fluorescence quenching in emission spectra points at the
decrease of luminescence properties of water-soluble porphyrins examined and can be predominantly attributed to
the process of static quenching. The order of calculated
fluorescence quenching constants values is in good agreement with data presented previously in literature [38]. The
most distinct decay of fluorescence intensity can be observed in case of H2TTMePP porphyrin.
3. The obtained data can be applied in determination of
porphyrin interactions and their decay kinetics. The results
could become as well a base for the elaboration of a new
artificial caffeine sensor, potentially useful for monitoring of
caffeine sewage in aqueous environment.
Open Access This article is distributed under the terms of the Creative Commons Attribution License which permits any use, distribution,
and reproduction in any medium, provided the original author(s) and
the source are credited.
References
1. Osowski A, Pietrzak M, Wieczorek Z, Wieczorek J (2010) Natural
compounds in the human diet and their ability to bind mutagens
prevents DNA-mutagen intercalation. J Toxicol Env Heal A
73:1141–1149
2. Piosik J, Gwizdek-Wisniewska A, Ulanowska K, Ochocinski J,
Czyz A, Wegrzyn G (2005) Methylxanthines (caffeine, pentoxifylline and theophylline) decrease the mutagenic effect of daunomycin, doxorubicin and mitoxantrone. Acta Biochim Pol 52:923–926
3. Woziwodzka A, Gwizdek-Wisniewska A, Piosik J (2011) Caffeine,
pentoxifylline and theophylline form stacking complexes with IQtype heterocyclic aromatic amines. Bioorg Chem 39:10–17
4. Piosik J, Zdunek M, Kapuscinski J (2002) The modulation by
xanthines of the DNA-damaging effect of polycyclic aromatic
agents. Part II. The stacking complexes of caffeine with doxorubicin and mitoxantrone. Biochem Pharmacol 63:635–646
5. Zdunek M, Piosik J, Kapuscinski J (2000) Thermodynamical
model of mixed aggregation of ligands with caffeine in aqueous
solution. Part II. Biophys Chem 84:77–85
6. Kapuscinski J, Kimmel M (1993) Thermodynamical model of
mixed aggregation of intercalators with caffeine in aqueous solution. Biophys Chem 46:153–163
7. Piosik J, Wasielewski K, Woziwodzka A, Sledz W, GwizdekWisniewska A (2010) De-intercalation of ethidium bromide and
propidium iodine from DNA in the presence of caffeine. Central
Eur J Biol 5:59–66
8. Lyles MB, Cameron II (2002) Interactions of the DNA intercalator
acridine orange, with itself, with caffeine, and with double stranded DNA. Biophys Chem 96:53–76
9. Evstigneev MP, Evstigneev VP, Davies DB (2006) NMR investigation of the effect of caffeine on the hetero-association of an
anticancer drug with a vitamin. Chem Phys Lett 432:248–251
10. Kapuscinski J, Ardelt B, Piosik J, Zdunek M, Darzynkiewicz Z
(2002) The modulation of the DNA-damaging effect of polycyclic
aromatic agents by xanthines. Part I. Reduction of cytostatic effects
of quinacrine mustard by caffeine. Biochem Pharmacol 63:625–634
11. Piosik J, Ulanowska K, Gwizdek-Wisniewska A, Czyz A, Kapuscinski
J, Wegrzyn G (2003) Alleviation of mutagenic effects of polycyclic
aromatic agents (quinacrine mustard, ICR-191 and ICR-170) by caffeine and pentoxifylline. Mutat Res 530:47–57
12. Ulanowska K, Piosik J, Gwizdek-Wisniewska A, Wegrzyn G (2005)
Formation of stacking complexes between caffeine (1,2,3-trimethylxanthine) and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine may attenuate biological effects of this neurotoxin. Bioorg Chem 33:402–413
13. Ulanowska K, Piosik J, Gwizdek-Wisniewska A, Wegrzyn G
(2007) Impaired mutagenic activities of MPDP+ (1-methyl-4phenyl-2,3-dihydropyridinium) and MPP+ (1-methyl-4-phenylpyridinium) due to their interactions with methylxanthines.
Bioorg Med Chem 15:5150–5157
14. Bolotin PA, Baranovsky SF, Evstigneev MP (2006) Spectrophotometric investigation of the hetero-association of caffeine and thiazine dye in aqueous solution. Spectrochim Acta A Mol Biomol
Spectrosc 64:693–697
15. Evstigneev MP, Rybakova KA, Davies DB (2006) Complexation
of norfloxacin with DNA in the presence of caffeine. Biophys
Chem 121:84–95
16. Mohanpuria P, Yadav SK (2009) Retardation in seedling growth
and induction of early senescence in plants upon caffeine exposure
is related to its negative effect on Rubisco. 47:293–297
17. Pollack K, Balazs K, Ogunseitan O (2009) Proteomic assessment
of caffeine effects on coral symbionts. Environ Sci Technol
43:2085–2091
18. Olesen CF, Cedergreen N (2010) Glyphosate uncouples gas exchange and chlorophyll fluorescence. Pest Manag Sci 66:536–542
19. Kolotov BA, Demidov VV, Volkov SN (2003) Chlorophyll content
as a primary indicator of the environment degradation due to
contamination with heavy metals. Dokl Biol Sci 393:550–552
20. Sauve S, Aboulfadl K, Dorner S, Payment P, Deschamps G, Prévost
M (2012) Fecal coliforms, caffeine and carbamazepine in stormwater
collection systems in a large urban area. Chemosphere 86:118–123
21. Ogunseitan OA (1996) Removal of caffeine in sewage by Pseudomonas putida: implications for water pollution index. Word J
Microb Biot 12:251–256
22. Vazquez-Roig P, Andreu V, Blasco C, Pico Y (2010) SPE and LCMS/MS determination of 14 illicit drugs in surface waters from the
Natural Park of L’Albufera (Valencia, Spain). Anal Bioanal Chem
397:2851–2864
23. Bindig U, Ulatowska-Jarza A, Kopaczynska M, Muller G, Podbielska
H (2008) Investigations on photolon- and porphyrin-doped sol–gel
fiberoptic coatings for laser-assisted applications in medicine. Laser
Phys 18:63–72
24. Holowacz I, Ulatowska-Jarza A, Wysocka K, Gluchowski P, Strek
W, Podbielska H (2008) Fluorescence properties of sol–gel materials doped with photosensitizers. Opt Apel 38:49–56
25. Podbielska H, Ulatowska-Jarza A, Muller G, Holowacz W, Bauer
J, Bindig U (2007) Silica sol–gel matrix doped with Photolon
molecules for sensing and medical therapy purposes. Biomol Eng
24:425–433
�J Fluoresc
26. Zawacka-Pankau J, Krachulec J, Grulkowski I et al (2008) The p53 mediated cytotoxicity of photodynamic therapy of cancer:
recent advances. Toxicol Appl Pharm 232:487–497
27. Makarska M, Pratviel G (2008) Long-range charge transport
through double-stranded DNA mediated by manganese- or ironporphyrins. J Biol Inorg Chem 13:973–979
28. Makarska M, Radzki S (2000) Spectrophotometric investigation of
the interaction between cationic porphyrins and adenine, adenosine
or ATP. Chem Listy 94:911
29. Machado GS, Castro KADF, de Lima OJ, Nassar EJ, Ciuffi KJ,
Nakagaki S (2009) Aluminosilicate obtained by sol–gel process as
support for an anionic iron porphyrin: Development of a selective
and reusable catalyst for oxidation reactions. Colloid Surface A
349:162–169
30. Cai JH, Huang JW, Zhao P, Zhou YH, Yu HC, Ji LN (2008)
Photodegradation of 1,5-dihydroxynaphthalene catalyzed by
meso-tetra-(4-sulfonatophenyl)porphyrin in aerated aqueous solution. J Mol Catal A-Chem 292:49–53
31. Neves CMB, Simoes MMQ, Santos ICMS, Domingues FMJ,
Neves MGPMS, Almeida Paz FA, Silva AMS, Cavaleiro JAS
(2011) Oxidation of caffeine with hydrogen peroxide catalyzed
by metalloporphyrins. Tetrahedron Lett 52:2898–2902
32. Buntem R, Intasiri A, Lueangchaichaweng W (2010) Facile synthesis
of silica monolith doped with meso-tetra(p-carboxyphenyl) porphyrin as a novel metal ion sensor. J Colloid Interf Sci 347:8–14
33. Johnson BJ, Melde BJ, Thomas C, Malanoski AP, Leska IA,
Charles PT, Parrish DA, Deschamps JR, Fluorescent silicate materials for the detection of paraoxon. Sensors 10:2315–2331
34. Pasternack RF, Gibbs EJ, Gaudemer A (1985) Molecular complexes of nucleosides and nucleotides with a monomeric cationic
porphyrin and some of its metal derivatives. J Am Chem Soc
107:8179–8186
35. Hambright P, Fleischer EB (1970) The acid–base equilibria, kinetics of copper ion incorporation and acid-catalyzed zinc ion displacement from the water-soluble porphyrin α, β, γ, δ-tetra(4-Nmethylpyridyl)porphine. Inorg Chem 9:1757–1761
36. Vilaplana RA, Gonzalez-Vilchez F, Pasternack RF (1991) Formation of supramolecules in solution. Interaction between transitionmetal complexes and water-soluble porphyrins. J Chem Soc Dalton Trans 1831–1834
37. Beck MT (1970) Chemistry of complex equilibria. Van Nostrand
Reinhold Company, London
38. Lakowicz JR (2006) Principles of fluorescence spectroscopy.
Springer, 3rd edition
39. Wang YQ, Zhang HM, Zhou QH (2009) Studies on the interaction of
caffeine with bovine hemoglobin. Eur J Med Chem 44:2100–2105
40. Merritt E (1926) The relation between intensity of fluorescence
and concentration in solid solutions. J Opt Soc Am 12:613–618
41. Chen RF, Knutson JR (1988) Mechanism of fluorescence concentration quenching of carboxyfluorescein in liposomes – energytransfer to nonfluorescent dimers. Anal Biochem 172:61–77
42. Robeson JL, Tilton RD (1995) Effect of concentration quenching
on fluorescence recovery after photobleaching measurements. Biophys J 68:2145–2155
43. Beddard GS, Carlin SE, Porter G (1976) Concentration quenching
of chlorophyll fluorescence in bilayer lipid vesicles and liposomes.
Chem Phys Lett 43:27–32
44. Chaudhuri KD (1959) Concentration quenching of fluorescence in
solutions. Zeitschrift fur Physik 154:34–42
45. Buchler JW (1978) Synthesis and properties of metalloporphyrins.
In: Dolphin D (ed) The Porphyrins, vol. I. Academic, New York
46. Gouterman M (1978) Optical spectra and electronic structure of
porphyrins and related rings. In: Dolphin D (ed) The Porphyrins,
vol. III. Academic, New York
47. Tabata M, Sakai M, Yoshioka K (1990) Proton nuclear magnetic
resonance spectrometric and spectrophotometric studies on hydrophobic and electrostatic interaction of cationic water-soluble porphyrin with nucleotides. Anal Sci 6:651–656
48. Zvezdanovic J, Cvetic T, Veljovic-Jovanovic S, Markovic D (2009)
Chlorophyll bleaching by UV-irradiation in vitro and in situ: Absorption and fluorescence studies. Radiat Phys Chem 78:25–32
49. Wang YQ, Zhang HM, Zhang GC, Tao WH, Fei ZH, Liu ZT
(2007) Spectroscopic studies on the interaction between silicotungstic acid and bovine serum albumin. J Pharmaceut Biomed
43:1869–1875
50. Hartman PE, Shankel DM (1990) Antimutagens and anticarcinogens – a survey of putative interceptor or molecules. Environ Mol
Mutagen 67:145–182
51. Fiammengo R, Crego-Calama M, Timmerman P, Reinhoudt DN (2003)
Recognition of caffeine in aqueous solutions. Chem Eur J 9:784–792
52. Gonzales-Jimenez J, Frutos G, Cayre Y (1992) Fluorescence
quenching of human serum albumin by xanthines. Biochem Pharmacol 44:824–826
53. Zhang HM, Chen TT, Zhou QH, Wang YQ (2009) Binding
of caffeine, theophylline, and theobromine with human serum albumin: A spectroscopic study. J Mol Struct 938:221–
228
54. Dashwood R, Yamane S, Larsen R (1996) Study of the forces
stabilizing complexes between chlorophylls and heterocyclic
amine mutagens. Environ Mol Mutagen 27:211–218
55. Mejri M, BenSouissi A, Aroulmoji V, Roge B (2009) Hydration
and self-association of caffeine molecules in aqueous solution:
Comparative effects of sucrose and β–cyclodextrin. Spectrochim
Acta A 73:6–10
56. Bian W, Wei YI, Wang YP, Dong C (2006) Study on interaction of
caffeine and theophylline with bovine serum albumins. Spectrosc
Spect Anal 26:505–508
57. Zhang HM, Tang BP, Wang YQ (2010) The interaction of lysozyme with caffeine, theophylline and theobromine in solution. Mol
Biol Rep 37:3127–3136
58. Ye L (2008) Solvent effects on photophysical properties of copper
and zinc porphyrins. Chinese Sci Bull 53:3615–3619
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