Key words
Lithospermum erythrorhizon
- Boraginaceae - inflammatory bowel disease - shikonin - ulcerative colitis -
in vivo
Abbreviations
ANOVA:
one-way analysis of variance
AOM:
azoxymethane
COX-2:
cyclooxygenase-2
CRC:
colorectal cancer
DSS:
dextran sulfate sodium
FITC:
fluorescein isothiocyanate
GAPDH:
glyceraldehyde 3-phosphate dehydrogenase
IBD:
inflammatory bowel disease
IL-6:
interleukin-6
iNOS:
inducible nitric oxide synthase
MPO:
myeloperoxidase
NF-κ B:
nuclear factor-κ B
SEM:
standard error of the mean
STAT3:
signal transducer and activator of transcription-3
TGF-β 1:
transforming growth factor-β 1
UC:
ulcerative colitis
Introduction
CRC is a major health problem and a leading cause of death in industrialized countries
[1 ]. It is now well accepted that chronic inflammation is a main factor in the development
of cancer, since the continuous presence of proinflammatory cytokines such as IL-6
or TNF-α contribute to the carcinogenic process by modifying the normal survival, growth,
proliferation, and differentiation of intestinal stromal cells through the alteration
of genes that regulate these processes, such as p53 and Bcl2, among others [2 ], [3 ], [4 ]. In addition, the overexpression of proinflammatory enzymes, such as COX-2 or iNOS,
favors this tumorigenic microenvironment by increasing oxidative stress and inhibiting
endogenous mechanisms of DNA repair [5 ]. NF-κ B activation has also been demonstrated to be essential in tumor growth and progression
[6 ], which further highlights the importance of inflammation in CRC development.
IBD, and especially long-time established UC, represents an example of a disorder
that increases the risk of CRC considerably. This risk depends on several factors,
such as the duration of the preexisting colitis, its anatomic extension, and the degree
of inflammation [7 ]. It is estimated that the risk of CRC development in a patient with UC can rise
as high as 40% after 40 years of disease, while 50 – 80% of colonic neoplasms may
remain undetected during a routine colonoscopy [7 ], which highlights the urgent need to develop effective chemopreventive drugs.
Traditional medicine based on the use of medicinal plants and their products has provided
first-line drugs for centuries, and has been an important source of therapeutic agents
developed by the pharmaceutical industry [8 ]. The dry root of Lithospermum erythrorhizon Siebold et Zucc. (Boraginaceae), also known as Zicao, contains the naphtoquinone
shikonin ([Fig. 1 ]) as its principal active molecule. Various preparations containing shikonin are
still used today for medicinal and cosmetic purposes in Asia, with Zicao being a commonly
used anticancer herbal medicine in China [9 ]. Shikonin has been studied in a mouse model of acute UC [10 ] with promising results: oral administration of this naphthoquinone prevented UC
development through the downregulation of Th1 responses together with the blockade
of two major IBD targets, NF-κ B and STAT3. Moreover, as previously published, shikonin stimulates the migration
of intestinal epithelial cells in vitro through a TGF-β 1-dependent process [11 ], a mechanism that probably complements its anti-inflammatory activity demonstrated
in vivo to prevent the development of UC by ulcers in the epithelial monolayer. The number
of studies highlighting the potential anticancer activity of shikonin and shikonin-containing
mixtures is increasing exponentially, and, although the precise underlying mechanism
is still undetermined, it seems clear that this naphthoquinone is capable of inhibiting
or modulating several molecular targets associated with cancer, as well as activating
multiple cell death pathways [12 ].
Fig. 1 Chemical structure of shikonin.
In light of these antecedents, the aim of this study was to evaluate the ability of
shikonin to prevent the early phases of colorectal cancer (before tumors are visible)
in vivo , and to explore its cytotoxic mechanism in vitro .
Results
The weight of the animals during the experimental period was not significantly affected
by any of the treatments administered ([Fig. 2 A, B ]). The weekly fluctuations observed, with weight loss during the odd-numbered weeks
and weight gain during the even-numbered weeks, coincided with the cycles of DSS administration.
Colitis was exacerbated on the days on which DSS was administered, while there was
a temporal remission of inflammation, which favored weight gain, on the days on which
animals received water only.
Fig. 2 Experimental protocol and macroscopic results. A Schematic representation of the AOM/DSS experimental protocol. B Evolution of weight during the experimental protocol. C Effect of shikonin on colon length. Statistical analysis was performed using ANOVA
followed by Dunnettʼs t-test; ***p < 0.001 vs. AOM/DSS group (n = 10).
Nevertheless, both sulfasalazine (positive control) and shikonin treatment significantly
protected the intestinal tissue, preventing the shortening of the colorectum caused
by the development of the disease, and impeding ulcer formation ([Fig. 2 C ]). Moreover, histologic analysis showed a marked loss of the structure of the microvilli,
crypt distortion, lamina propria erosion, and erosion of the mucosal membrane, together with massive infiltration
of inflammatory cells, in the group of mice treated with AOM/DSS ([Fig. 3 B ]). In the case of sulfasalazine-treated mice ([Fig. 3 C ]), the crypt structure was, in general, conserved and there was less inflammatory
cell infiltration than in the AOM/DSS group. In addition, in some areas of the colon
we detected crypt elongation, which is a consequence of regeneration mechanisms working
faster than the shedding process, which causes cells to accumulate in the villi and
to become elongated as a result. Shikonin-treated mice ([Fig. 3 D, E ]) exhibited a clear dose-response. Those receiving the lower dose displayed more
inflammatory cell infiltration together with partial loss of the mucosa, and partial
loss and nonfunctional elongation of the crypts. In contrast, mice treated with the
highest dose showed lower cell infiltration and crypts that were better conserved
and functional when undergoing elongation processes. MPO activity is an indicator
of the extent of an inflammatory process, as it is an indirect determination of neutrophil
infiltration, and we found that it was significantly decreased by shikonin and sulfasalazine
([Fig. 4 A ]).
Fig. 3 Effect of shikonin treatment on histological parameters. Three representative colonic
hematoxylin/eosin sections: mice received fresh tap water (A ), AOM/DSS (B ), AOM/DSS + sulfasalazine treatment (C ), AOM/DSS + shikonin 3.5 mg/kg (D ), or AOM/DSS + shikonin 7 mg/kg (E ) (n = 10).
Fig. 4 Effect of shikonin on neutrophil infiltration and IL-6 production. A Mucosal MPO levels were measured to evaluate the effect of shikonin on the number
of neutrophils infiltrating the colon. MPO activity is expressed as U/g, that is,
the amount of enzyme required to convert 1 µmol of H2 O2 to water in 1 min, expressed per gram of wet tissue. B Effect of shikonin on IL-6 production in the colon. *P < 0.05, ***p < 0.001; significantly
different from the AOM/DSS group, determined by means of ANOVA followed by Dunnettʼs
t-test (n = 7).
Proinflammatory cytokines play an essential role in the development of CRC. The pleiotropic
cytokine IL-6 has been linked to the pathogenesis of sporadic and inflammation-associated
CRC, as demonstrated by several experimental and clinical studies [13 ]. Shikonin (7 mg/kg) blocked AOM/DSS-induced IL-6 production, with similar levels
detected in treated and untreated (sham) groups ([Fig. 4 B ]). However, sulfasalazine did not have an effect on IL-6 production.
According to our results, exposure to AOM/DSS causes a strong expression of COX-2
and iNOS, which is prevented by shikonin and by sulfasalazine ([Fig. 5 A, B ]). NF-κ B plays an essential role in immune and inflammatory responses, as demonstrated by
the fact that the promoter and enhancing regions of genes coding for inflammatory
mediators have binding sites for this transcription factor [14 ]. In this sense, patients with inflammatory bowel disease show high NF-κ B activation in lamina propria biopsies as well as elevated levels of macrophages and epithelial cells [15 ], [16 ]. Accordingly, we verified that levels of p65 were markedly higher in AOM/DSS-treated
animals than in the vehicle group, an increase that was blocked by shikonin treatment
([Fig. 5 C ]).
Fig. 5 Effect of shikonin treatment on proinflammatory mediators in colonic tissue. A Effect of shikonin on COX-2 expression. B Effect of shikonin on iNOS expression. C Effect of shikonin on nuclear translocation of the NF-κ B p65 subunit. The histograms at the top represent the data derived from the Western
blots following densitometry analysis (mean of the relative OD ± S. E.M); consider
the DSS + AOM group as having 100% expression. Levels were normalized against β -actin or the PARP-1 antibody. **P < 0.01, ***p < 0.001, ****p < 0.0001; significantly
different from the AOM/DSS group, determined by means of ANOVA followed by Dunnettʼs
t-test (n = 6 – 8).
The MTT cytotoxicity assay revealed a dose-dependent in vitro cytotoxic effect of shikonin (IC50 = 9.84 µM) ([Fig. 6 ]). To investigate whether shikonin was affecting cell cycle regulation, we determined
its effect in Caco-2 cells by flow cytometry and compared it to the effect of the
known cytotoxic compound actinomycin D. Twenty-four-hour exposure of Caco-2 cells
to shikonin resulted in a statistically significant decrease of cell subpopulations
in the preparatory phases of the cycle, G0 /G1 and G2 /M, accompanied by an increase in the S phase, in a concentration-dependent manner.
These results reveal that shikonin induces the metabolic activation of these cells,
which is favorable in the treatment of cancer, as it reduces the percentage of cells
that remain quiescent in the G0 /G1 phase, increasing their susceptibility to cytotoxic treatments ([Fig. 7 ]).
Fig. 6 Evaluation of the cytotoxic effect of shikonin in Caco-2 cells. Differences between
each group and the control group were determined by means of ANOVA followed by Dunnettʼs
t-test. *P < 0.05, **p < 0.01, ***p < 0.001; ns: not significantly different (n = 8).
Fig. 7 The cell cycle of Caco-2 cells (A ) left untreated, (B ) treated with actinomycin D-treated, or (C –F ) treated with increasing doses of shikonin was analyzed by flow cytometry. The histogram
(G ) represents the % of cells in each phase of the cell cycle for each treatment. Significant
differences in each phase of each treated group with respect to the control group
were determined by means of a two-way analysis of variance followed by Dunnettʼs t-test,
where *p < 0.05, **p < 0.01, ****p < 0.0001 (n = 8).
Finally, as seen in the cell cycle analysis, shikonin exerted a proapoptotic effect,
as demonstrated by the increase of the subpopulation of Caco-2 cells during the SubG0 phase; in other words, it increased the fragmentation of DNA. Since this increase
could also have been caused by a direct cytotoxic effect like that which occurs in
necrotic processes, we stained cells with propidium iodide and FITC-Annexin V to differentiate
apoptotic and necrotic cells. Shikonin significantly and dose-dependently exerted
a proapoptotic effect on Caco-2 cells ([Fig. 8 ]). This is in line with the known effects of shikonin on other cancer cell lines
[17 ], [18 ]. Moreover, to delve into the mechanism of action by which shikonin induces apoptosis
in these cells, we employed Western blot to analyze the expression of the antiapoptotic
protein Bcl-2 and the proapoptotic caspase 3. As demonstrated in [Fig. 9 ], treatment with shikonin inhibited the expression of Bcl-2 and induced the activation
of caspase 3 is a dose-dependent manner, all of which indicates that shikonin stimulates
the apoptotic process by acting on the proapoptotic machinery of the cells.
Fig. 8 Shikonin triggers apoptosis in Caco-2 cells. Normal, apoptotic, and necrotic cells
were assessed by flow cytometry using Annexin V and propidium iodide (PI) staining.
Cells in the lower left quadrant (Annexin V-FITC− /PI− ) are normal, those in the lower right quadrant (Annexin V-FITC+ /PI− ) are early apoptotic cells, and those in the upper right quadrants (Annexin V-FITC+ /PI+ ) are late apoptotic or necrotic. (A ) Left untreated, (B ) treated with actinomycin D-treated, or (C –F ) treated with increasing doses of shikonin. The histogram (G ) represents the data obtained from eight independent experiments, expressed as the
mean ± S. E. M. Differences between each group and the control group were determined
by means of a two-way analysis of variance followed by Dunnettʼs t-test; *p < 0.05,
**p < 0.01, ****p < 0.0001.
Fig. 9 Modulation of the apoptotic machinery by shikonin treatment. The histograms at the
top represent the data derived from the Western blots following densitometry analysis.
The bottom panels show an example of Western blot following probing with the corresponding
antibody. Levels were normalized against the GAPDH antibody. A Effect of shikonin on Bcl-2 expression. B Effect of shikonin on caspase-3 activation. **P < 0.01, ***p < 0.001, ****p < 0.0001;
significantly different from the control group, determined by means of ANOVA followed
by Dunnettʼs t-test (n = 5).
Discussion
It is a proven fact that the risk of developing CRC is higher in patients with IBD
than in the rest of the population [19 ]. The discomfort associated with a colonoscopy, used indiscriminately as a population
screening method, has favored an increased interest in the use of chemopreventive
strategies that reduce the risk of cancer, extending their benefits to IBD patients.
Since chronic inflammation is a clear procarcinogenic factor, it seems logical that
anti-inflammatory agents have potential as chemopreventive agents. However, to date,
no anti-inflammatory drug has demonstrated this property, with the exception of 5-amino-salicylic
acid (5-ASA) and related immunosuppressive thiopurines [20 ]. In this sense, further studies are needed to confirm the chemopreventive effect
of other anti-inflammatory drugs in spontaneous colorectal cancer prevention. On this
premise, we have studied the chemopreventive effect of shikonin, a natural product
with proven anti-inflammatory [10 ], [21 ] and wound healing [11 ] activities, in a model in which the synergic effects of AOM (the tumor-inducing
agent) and DSS (which produces severe colitis due to its toxicity to the epithelial
lining of the colon) reproduce the initial acute inflammatory phase that precedes
the carcinogenesis that occurs in human CRC [1 ]. We have observed how the said phase was clearly reproduced, especially in the distal
part of the colon (as occurs in humans), where an inflammatory process could be observed
in the mucosa and submucosa, together with damage to and loss of the majority of the
crypts. In line with previous research [22 ], sulfasalazine administration to mice treated with AOM/DSS partially blocked this
inflammatory precancerous process, as did treatment with shikonin.
The activity of the disease is linked to the influx of neutrophils in the mucosa and
consequently in the intestinal lumen, which leads to the formation of abscesses in
the crypts. As would be expected in a subchronic process, leukocyte infiltration,
largely responsible for the pathogenesis of UC, was markedly increased in AOM/DSS-treated
mice, evident in the increase of MPO activity in the colonic tissue of these animals.
It is known that, in the progression of UC-associated CRC, there is a massive infiltration
of neutrophils into the lamina propria and submucosa [23 ], and that an elevated ratio of neutrophil-to-lymphocyte predicts a significantly
higher risk of death in colon cancer [24 ]. Moreover, it has been demonstrated that neutrophil depletion decreases the different
parameters of DSS-induced colitis [25 ] and that administration of neutrophil-neutralizing antibodies after the last DSS
cycle markedly reduces the number and size of tumors and decrease the expression of
chemokines, matrix metalloproteinase-9, and neutrophil elastase in an AOM/DSS model
[24 ]. In our experiments, shikonin significantly reduced this infiltration to an even
greater extent than sulfasalazine. This depleted number of tumor-associated neutrophils
would result in a reduction in neutrophil-produced tumorigenic mediators (such as
metalloproteinases), therefore interfering with the progression of chronic colitis
to CRC.
As De Robertis M et al. [1 ] described, key components of cancer-promoting inflammation that have been investigated
in the AOM/DSS model include proinflammatory cytokines, such as IL-6 and TNF-α , COX-2, and master transcription factors, such as NF-κ B and STAT-3. Clinical and experimental data show that IL-6 contributes considerably
to both sporadic and colitis-associated colorectal cancer [13 ]. In our experimental procedure, sulfasalazine did not prevent the increase of IL-6
induced by AOM/DSS-treatment; in contrast, shikonin did significantly inhibit this
cytokine. Growing evidence supports a critical role for IL-6 signaling during CRC
development, and so therapeutics that target this cytokine are viewed as promising
options for the treatment of IBD [13 ], [26 ].
COX-2 and iNOS were also inhibited by shikonin treatment in our experiments. The expression
of COX-2 is increased in 40% of colorectal adenomas and in 80% of CRCs [27 ], mainly in neoplastic epithelial cells [28 ], and is associated with tumor development and progression. iNOS, on the other hand,
is activated in large bowel neoplasms and dysplasia within 20 weeks of the initiation
of AOM/DSS treatment [1 ]. In our experiment, the expression of these two enzymes was significantly increased
in the colitic group when compared to the untreated (sham) group, as expected. However,
shikonin significantly inhibited the increase of these proinflammatory enzymes to
the same extent as the control treatment sulfasalazine. The activation of the transcription
factor NF-κ B is probably involved in the overexpression of the aforementioned proinflammatory
enzymes and cytokine (COX-2, iNOS, and IL-6), as it is implicated in the regulation
of inflammatory and immunomodulatory genes, as well as antiapoptotic genes. Shikonin,
in the same way as sulfasalazine, significantly inhibits the activation of this transcription
factor, the lynchpin of inflammation-associated cancer [29 ], and consequently leads to a reduction in the expression of proinflammatory cytokines,
adhesion molecules, and antiapoptotic genes [7 ].
Our in vitro results are consistent with this scenario. In vitro shikonin induces the proapoptotic Bcl-2 and inhibits the antiapoptotic caspase 3.
Although previous studies carried out by other groups [17 ], [18 ] have demonstrated shikoninʼs cytotoxic effect in other cell lines, this is the first
time that the cytotoxic effect of shikonin has been demonstrated in the human epithelial
colorectal adenocarcinoma cell line Caco-2. Our results confirm those of other authors
who claim that shikonin modifies the cell cycle of cancer cells through the accumulation
of these cells during the G0 phase, which decreases the subpopulations of G0 /G1 , S, and G2 /M in human melanoma cells (A375-S2) and murine melanoma (B16F10) [18 ], [30 ]. The reduction of the population of cells in a quiescent phase (G0 ) increases the susceptibility of these cells to conventional anticancer treatments.
In fact, studies in chemoresistant cell lines (MCF-7/Adr) combining shikonin with
other reference antitumor drugs (such as paclitaxel or vincristine) have demonstrated
the chemosensitizing ability of the former, yielding antitumor activity values similar
to those presented by the drug alone [17 ]. It is worth noting that clinical studies in patients with advanced lung cancer
treated with conventional chemotherapy together with shikonin show a decrease in proliferation
and tumor growth, longer survival, and a general improvement of their immune functionality
and quality of life thanks to a decrease in the general perception of pain, improvement
of appetite, and weight gain [31 ].
In conclusion, shikonin acts as a chemopreventive agent in the AOM/DSS model of UC-associated
CRC through inhibition of the proinflammatory milieu generated during the disease
and known to be an important risk factor in cancer development. Moreover, previous
studies have demonstrated that shikonin has wound healing properties in vivo
[32 ], [33 ] and in vitro in intestinal epithelial cell lines [11 ]. We hypothesize that this wound healing capacity is also at play in the UC model,
contributing to the healing of ulcers and therefore reducing the bacterial influx
from the intestinal lumen, which in turn diminishes inflammation. Finally, we propose
that shikonin inhibits or modulates cellular targets associated with cancer and activates
multiple cell death pathways either directly or indirectly [12 ], and that this cytotoxic effect contributes to the positive results of shikonin
in this model. Although these two last hypotheses need to be confirmed by more in-depth
studies in the model, we consider that the present evidence points to shikonin as
a highly promising therapeutic agent.
Materials and Methods
Chemicals
Shikonin (≥ 98% purity by HPLC) was purchased from TCI Europe. DSS (molecular weight
36 – 50 kD; MP Biomedicals LLC), sulfasalazine (≥ 98% purity by HPLC), AOM (≥ 98%
purity by HPLC), and actinomycin D (≥ 95% purity by HPLC) were purchased from Sigma-Aldrich.
All chemical and biochemical reagents used in the buffers and experimental protocols
were purchased from Fluka Chemika-Biochemika, Baker, Panreac, and Sigma-Aldrich.
Animals
Female Balb/C mice weighing 18 – 20 g (Janvier) were used for the in vivo experiments. All animals were fed a standard diet ad libitum and housed under a 12-h
light/dark cycle at 22 ± 3 °C and 60% humidity. Housing conditions and all in vivo experiments were approved by the Institutional Ethics Committee of the University
of Valencia, Spain (2015/VSC/PEA/00023; approved January 23, 2015).
Induction of colorectal cancer associated with chronic ulcerative colitis and treatment
with shikonin
We employed the AOM/DSS model of colitis-associated colorectal carcinogenesis [7 ], [34 ], as outlined in [Fig. 2 A ]. In brief, after 1-week acclimatization, female Balb/C mice were injected with AOM
(7.5 mg/kg, i. p.) and randomly assigned to four treatment groups (10 animals/group):
one group was left untreated, a second group received the standard drug sulfasalazine
(100 mg/kg), and the two remaining groups were treated with shikonin at two different
doses (3.5 and 7.0 mg/kg). Doses were selected based on previous experiments [10 ]. Both sulfasalazine and shikonin were dissolved in normal drinking water before
administration. Doses were calculated based on the estimation that mice drink about
6 mL of water/day. DSS treatment began one week after AOM injection and continued
for three cycles. Each cycle consisted of 7 days of 1.5% DSS (w/v) dissolved in fresh
tap water ad libitum followed by 7 days without DSS. During the 14 days that each
cycle lasted, both shikonin and sulfasalazine were administered on a continuous basis.
A fifth group (six animals; sham group) was left untreated, injected with saline (instead
of AOM), and drank normal drinking water throughout the experiment. Since the aim
of the present study was to establish the effect of shikonin on the initial stages
of CRC development, the endpoint of the procedure was established before visible tumors
could be observed, at the stage of subchronic colorectal inflammation.
Body weight and drinking were monitored throughout the experiment. No significant
difference in fluid consumption between groups was detected.
Upon termination of the experiment, colonic tissues from mid to distal colon were
excised, rinsed with cold PBS, and blotted dry. Following gross examination, a piece
(approximately 1 cm) of each colon was separated for histological evaluation and the
rest was left for biochemical analyses. Those samples set aside for biochemical tests
were ground to powder with a mortar and kept at − 80 °C for further analyses.
Histopathological analysis
Small (approximately 1 cm) frozen sections (4 µm) of excised colonic tissue were fixed
in 10% paraformaldehyde in PBS (pH 7.4) and stained with hematoxylin and eosin. Histologic
assessment of the degree of inflammation and dysplasia of the colonic mucosa was carried
out in a blinded fashion by a pathologist.
Myeloperoxidase activity assay
MPO activity was determined as previously described [35 ]. About 40 mg of powdered tissue was weighed for each sample and homogenized in 80 mM
KH2 PO4 /Na2 HPO4 buffer (pH 5.4) containing 0.5% hexadecyltrimethylammonium bromide. After centrifugation
(11 300 g for 20 min at 4 °C), 100 µL of PBS, 85 µL of 22 mM KH2 PO4 /Na2 HPO4 buffer, and 15 µL of H2 O2 0.017% were added to 30 µL of the supernatant. The enzymatic reaction began when
adding 20 µL of tetramethylbenzidine hydrochloride. After 3 min at 37 °C the reaction
was stopped. Absorbance was read at 630 nm. MPO activity is expressed as the amount
of enzyme required to convert 1 µmol of H2 O2 to water in 1 min, expressed per gram of wet tissue.
Measurement of interleukin-6 in colon tissue
The concentration of IL-6 in the colon was measured using an enzyme-linked immunosorbent
assay kit (eBioscience) following the manufacturerʼs instructions. About 80 mg of
dry powdered tissue was dissolved (20%, w/v) in ice-cold PBS buffer containing 0.1%
Igepal CA-630, as described in a previous study [36 ], and a complete mini-EDTA-free protease inhibitor cocktail was added (Roche). Tissues
were sonicated for 10 s and shaken on ice for 45 min. The homogenates were centrifuged
(20 000 g for 10 min at 4 °C) and supernatants were collected and stored at − 80 °C. Protein
concentration in the supernatants was determined with the Bradford method.
Preparation of cytosolic and nuclear protein fractions from colon and analysis by
Western blot
Protein extraction from the intestine was performed as described previously [37 ]. Powdered tissues were homogenized for 1 min with a Polytron PT-2000 (Kinematica)
tissue homogenizer in 1.5 mL of ice-cold buffer A (10 mM HEPES pH 7.9, 10 mM KCl,
1.5 mM MgCl2 , 0.5 mM dithiothreitol, 0.1 mM EDTA, 0.5 mM phenylmethyl sulphonyl fluoride, 1 µg/mL
aprotinin, 1 µg/mL leupeptin, and 1 µg/mL pepstatin A]. Igepal CA-630 was added to
a final concentration of 0.5%. The homogenates were chilled on ice with gentle shaking
for 45 min. The membrane fraction was centrifuged at 106 × g for 10 min at 4 °C. The supernatant containing the cytosolic fraction was stored
at − 80 °C until use. The pellet was resuspended in 500 µL of buffer B (20 mM HEPES
pH 7.8, 400 mM NaCl, 1.5 mM MgCl2 , 0.2 mM EDTA, 25% glycerol, 0.5 mM phenylmethylsulphonyl fluoride, 0.5 mM dithiothreitol,
1 µg/mL aprotinin, 1 µg/mL leupeptin, and 1 µg/mL pepstatin A) and chilled for 30 min
on ice with gentle shaking. After centrifugation at 20 800 × g for 15 min at 4 °C, the supernatant containing the nuclear fraction was removed and
stored at − 80 °C until use.
The presence of proteins in the supernatants was determined by means of the Bradford
method, and equal amounts of protein (30 µg) were used. Membranes were incubated with
polyclonal antibodies against COX-2 (1 : 1000; Millipore), iNOS (1 : 2000; Millipore),
p65 (1 : 500; SC-7151; Santa Cruz Biotechnology), β -actin (1 : 10 000; Sigma-Aldrich), or PARP (1 : 500; Sigma-Aldrich). β -Actin was used as a cytosolic or total protein loading control and PARP was used
as a nuclear protein loading control. The blots were washed and incubated with peroxidase
conjugate anti-rabbit, anti-mouse, or anti-goat immunoglobulin G (1 : 12 000 dilution;
Sigma-Aldrich). The immunoreactive bands were visualized with the aid of an enhanced
chemiluminiscence system (Millipore).
Cell culture
Human epithelial colorectal adenocarcinoma Caco-2 cells (ATCC; passages 21 – 33) were
used in all in vitro experiments. Cells were maintained in DMEM GlutaMAX (Gibco) (1 g/L glucose) supplemented
with 20% fetal bovine serum, 1% antibiotics (penicillin (100 U/mL), and streptomycin
sulfate (100 mg/mL) in a humidified 5% CO2 atmosphere.
Proliferation and cytotoxicity assay
The effect of shikonin on proliferation and cytotoxicity was evaluated with the MTT
assay [38 ]. Caco-2 cells were exposed to shikonin (50 – 1.56 µM) or to actinomycin D (4 µM)
in a 96-well microplate and, 24-h post-treatment, 100 µL per well of a 0.5 mg/mL solution
of MTT (Sigma-Aldrich) were added. Absorbance was measured at 490 nm with a Victor
X3 (Perkin Elmer) plate reader. Untreated cells were arbitrarily assigned 100% viability.
Actinomycin D was used as a reference compound in cell studies, as it inhibits the
growth of tumor cells, thus inducing apoptosis through a mechanism that involves the
irreversible alteration of gene replication and protein transcription, together with
the inhibition of topoisomerase II and an increase in the production of reactive oxygen
species [39 ].
Preparation of cell samples and Western blot analysis
Caco-2 cells were plated at a density of 5 × 105 cells per well in a 6-well cell culture plate along with 2 mL of culture medium and
then incubated for 24 h. The cells were pretreated with shikonin or actinomycin D
and subsequently stimulated with lipopolysaccharide (1 mg/mL) for the specified periods
(16 – 24 h).
For Western blot, cell lysates were obtained with lysis buffer [1% Triton X-100, 1%
deoxycholic acid, 20 mM NaCl, and 25 mM Tris, pH 7.4 (Sigma-Aldrich), and a complete
mini-EDTA-free protease inhibitor cocktail]. After centrifugation, proteins were determined
in the supernatant by the Bradford method. Membranes were incubated with polyclonal
antibodies against Bcl-2 (1 : 500, SC-7382), caspase-3 (1 : 500, SC-22139), or GAPDH
(1 : 1000, SC-20357), all purchased from Santa Cruz Biotechnologies. GAPDH was used
as a loading control.
Cell cycle and apoptosis studies by flow cytometry
To study the effect of shikonin on the cell cycle by flow cytometry, a commercial
kit was used (BD Cycletest Plus DNA Reagent Kit, BD Biosciences). Samples were analyzed
according to the manufacturerʼs instructions.
Apoptosis was also studied by flow cytometry with the aid of a commercial kit (FITC-Annexin
V Apoptosis Detection Kit I, BD Biosciences).
Software
Images for all Western blot experiments were acquired with the image analysis system
LAS-3000 mini (Fujifilm). Digital images were processed and band density measurements
were made with the aid of a Multi Gauge V3.0 software package (Fujifilm).
Statistical analysis
Statistical analysis was performed by means of ANOVA followed by Dunnettʼs t-test.
The results are presented as the mean ± SEM. GraphPad Prism 4.0 software (GraphPad
Software Inc.) was used for all calculations.
