Figure 1. Cell
viability of SiHa, Hep2 and Ca Ski cells as measured by MTT
(3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide) assay. TR:
Tiazofurin. The results are the mean ± SE of three different experiments.
Gene Ther Mol Biol Vol 10, 199-206,
2006
Apoptotic signaling induced by Tiazofurin-an in vitro study
Sujata Pathak1, Himani Sharma1, Chandresh
Sharma1, Hiremagalur N. Jayaram2, Neeta Singh1,*
1Department of Biochemistry, All India Institute of
Medical Sciences, New Delhi-110029, India
2Department of Biochemistry and Molecular Biology,
Indiana University School of Medicine and Richard Roudebush Veterans Affairs
Medical Center-151,
Indianapolis, Indiana IN 5122, USA
__________________________________________________________________________________
*Correspondence: Dr. Neeta Singh, Professor, Department of
Biochemistry, Room No 3027A, All India Institute of Medical Science, Ansari
Nagar, New Delhi 110029, India; Tel: 91-11-26588663; Fax: 91-11-26594945; E
mail: singh_neeta26@rediffmail.com
Key words: Tiazofurin, apoptosis, mitochondria, cytochrome c
Abbreviations: apoptosis
inducing factor, (AIF); cerebellar granule cells, (CGCs); human colorectal
carcinoma, (RKO); inosine 5Õ mono phosphate dehydrogenase, (IMPDH);
nicotinamide 5Õ mononucleotide adenylyltransferase, (NMNAT); phosphate-buffered
saline, (PBS); poly, (ADP-ribose) polymerase, (PARP); propidium iodide, (PI);
Relative Units, (RU); thiazole-4-carboxamide adenine dinucleotide, (TAD); Tiazofurin,
(TR); Tris buffered saline, (TBS)
Summary
Tiazofurin (TR), is a novel anticancer agent exhibiting potent
cytotoxic activity in malignant cell lines. It exhibits at least two different
mechanisms of action. First is by inhibition of inosine 5Õ monophosphate
dehydrogenase (IMPDH), a rate-limiting enzyme for guanylate (GTP, dGTP)
biosynthesis and second is by the induction of apoptosis. But the mechanism of
induction of apoptosis is not clear. The purpose of the present study was to
elucidate the apoptotic signaling induced by TR in different human cancer cell
lines. The effect of TR was studied on SiHa (human cervical cancer cell line),
Hep2 (human laryngeal cancer cell line) and Ca Ski (human cervical cancer cell
line) cells. Morphological examination, flowcytometry and Caspase-3
assay were used for detection of apoptosis. Expression of various proteins was
seen by Western blotting. Our
results reveal that TR at a dose of 100μM induces apoptosis in SiHa and
Hep2 cells whereas for Ca Ski cells this dose is 150μM as studied by
morphology and flow cytometry. A downregulation of anti-apoptotic proteins
Bcl-2 and Bcl-xL was observed whereas the expression level of the pro-apoptotic
protein Bax remained unaffected in all these cell lines. An upregulation of p53
was observed while no change was seen on the level of apoptosis inducing factor
(AIF). A moderate increase in caspase-9 activity was seen. There was a
significant increase in caspase-3 activity, which was accompanied by PARP
cleavage. Release of cytochrome c from the mitochondria to the cytosol was also
observed. The findings suggest that TR induces apoptosis in SiHa, Hep2 and Ca
Ski cells via the intrinsic mitochondrial pathway.
Apoptosis is a genetically controlled
process of cell death. Signaling for apoptosis occurs through multiple
independent pathways that are initiated either from triggering events within
the cell or from outside the cell. Finally the apoptosis signaling pathways
converge on a common machinery of cell destruction that is activated by a
family of cysteine proteases (caspases) that cleave proteins at aspartate
residues, causing degradation of cellular proteins and disassembly of the cell,
leading to morphological changes such as chromatin condensation, nuclear
shrinkage and the formation of apoptotic bodies (Borner, 2003).
In general terms, apoptotic pathways can
be sub-divided into two categories- extrinsic apoptotic signals by ligand
engagement of cell surface receptors such as Fas and TNF receptors, and
intrinsic pathways activated by signals emanating from cellular damage sensors
(e.g. p53) or development cues. Although the pathways activated by extrinsic
and intrinsic signals can overlap to some extent, receptor ligation typically
leads to recruitment of adaptor proteins that promote caspase oligomerization
and auto-processing (Ashkenazi and Dixit, 1998). Intrinsic signals usually
operate by triggering the release of proteins from the intermembrane space of
the mitochondria to the cytosol (Green and Reed, 1998). Most notable among
these is cytochrome c; binding of cytochrome c to a central apoptotic
regulator, Apaf-1 promotes oligomerization of Apaf-1 and activation of
caspase-9 (Budihardjo et al, 1999). Caspase -9 subsequently activates effector
caspases such as caspase -3, -6 and -7. The molecular participants of apoptosis
are located in mitochondria, plasma membrane, cytosol, nucleus, with interplay
between these compartments. The pathways converge at two main initiator
caspases-8 and -9 to signal via distinct receptor or mitochondrial mediated
pathways and activate the effectors pro-caspase-3 within the cytosol. The
release of mitochondrial proteins is blocked by the anti-apoptotic Bcl-2 family
members and promoted by pro-apoptotic members. Majority of chemotherapeutic
agents trigger the mitochondrial pathway, but the death receptors have also
been reported to be involved in chemotherapy induced apoptosis (Yuan and Whang,
2002; Calviello et al, 2003).
Tiazofurin
(TR: 2-b-D-ribofuranosylthiazole-4-carboxamide)
exhibits cytotoxicity in vitro. The mechanism of action of TR is thought to be
due to he conversion to its active metabolite, an analogue of NAD,
thiazole-4-carboxamide adenine dinucleotide (TAD). TAD, in turn is a potent
inhibitor of inosine-5Õ-mono phosphate dehydrogenase (IMPDH) which is a
rate-limiting enzyme involved in the synthesis of guanylates (GTP and dGTP). Tiazofurin
has been extensively studied both in pre-clinical (Jayaram et al, 1999) and
clinical studies (Tricot et al, 1989; Wright et al, 1996), and has been
approved for treatment of patients with acute myeloid leukaemia in blast crisis
(Grifantini, 2000). Recently, studies from our
laboratory have shown that another IMPDH inhibitor benzamide riboside possibly
exerts its apoptotic effect through the mitochondrial mediated pathway in human
lung cancer H520 cells (Khanna et al, 2004). The thrust of the present study
was to investigate the mechanism of induction of apoptosis by TR using
different human malignant cell lines. An understanding of the mechanism of
induction of apoptosis with TR is of interest since this may help to develop a
novel approach to treat cancer.
A. Materials
TR was obtained from the Drug
Synthesis and Chemistry Branch, Division of Cancer Treatment, National Cancer
Institute, Bethesda, MD, USA.
The cell lines were obtained from National Centre for Cell Science, Pune,
India. Caspase-3 assay kit was from Pharmingen, Germany and Caspase-8 and -9
substrates were obtained from Genotech, USA. Western blot kit was purchased
from Promega Corporation, USA. Bcl-2, Bcl-xL, Bax, p53, AIF and cytochrome
c antibodies were obtained from Santa Cruz, USA. PARP antibody was purchased
from Neo Markers, USA.
B. Cell culture and treatments
Human malignant cell lines SiHa (human
cervical cancer cell line) and Hep2 (human laryngeal cancer cell line) were
grown in DMEM medium whereas Ca Ski (human cervical cancer cell line) was grown
in RPMI medium. The media was supplemented with 10% fetal calf serum and
antibiotics in a humified atmosphere of 5% CO2 in air, at 370C.
Logarithmically growing cells were used for all experiments. TR was dissolved
in autoclaved double distilled water. The cells were treated with TR for 24 hr.
The IC50 of TR had been studied on the basis of MTT assay and flow
cytometry. The calculated IC50 has been used for all subsequent
experiments. Treatment with cisplatin in the above cell lines was used as
positive control. Normal human lymphocytes were used as controls.
C. MTT (cell viability) assay
The growth inhibitory effect of TR was
assessed by the MTT assay. Briefly, 1x104 cells were seeded in a
96-well microtiter plate. Cells were then treated with different concentrations
(50μM, 100μM, 150μM and 200μM) of tiazofurin for 24 hrs.
100μl of 5mg/ml of MTT was added followed by incubation for 4 hrs at 37¼C.
The formazan crystals thus formed were dissolved in DMSO and the absorbance was
measured at 570nm using an ELISA reader and 620nm as the reference wavelength (Sen
et al, 2005). IC50 of TR was found to be 100μM for SiHa and
Hep2 cells, whereas it was 150μM for Ca Ski cells.
D. Detection of apoptosis
1. Morphological analysis
Apoptotic cell death was evaluated by
observing morphological changes typical of apoptosis by light microscopy (Singh
et al, 2002).
2. Flow cytometry
Briefly, 2 x 106 cells were
washed once in phosphate-buffered saline (PBS) and fixed in 70% ethanol at -200C
overnight. Fixed cells were washed and resuspended in a buffer containing 5
mg/ml propidium iodide (PI), 0.1% sodium citrate, and 1% Triton-X-100. PI
stained cells were analyzed using a FACScan cytometer (Coulter) equipped with
an argon laser using Win MDI 2.8 software (Sharma et al, 2005).
3. Immunoblot analysis
The levels of expression
of Bcl-2, Bcl-xL, Bax, p53, AIF, PARP and cytochrome c were determined in
control and treated cells by Western blotting as described previously (Sharma
et al, 2005). Briefly, control and treated cells were washed twice in PBS
and lysed in RIPA lysis buffer containing protease and phosphatase inhibitors.
Protein quantification of the lysates was done by BradfordÕs method. Equal
amounts of protein extracts were then electrophoresed on 10-15% SDS-Polyacrylamide
gel depending upon the molecular weight of the protein, transferred to
nitrocellulose membrane, and nonspecific binding blocked with 5% BSA and 5% FCS
in Tris buffered saline (TBS) for 2.5hrs at 37¼C. The blot was washed with
0.05% Tween-20 in TBS and then TBS for 10 min each. The blot was incubated with
primary antibodies at 4¼C overnight against the protein of interest and then
incubated with secondary antibody conjugated to alkaline phosphatase for 2hrs
at room temperature, rinsed with 0.05% Tween-20 in TBS, then with TBS. This was
followed by addition of AP buffer and the bands visualized by adding BCIP and
NBT. The bands were analyzed and quantitated using a a-imager scanning densitometer (Alpha Innotech, USA). The protein
expression is expressed in Relative Units (RU). The density of the control was
taken as 1 and the results of treatments were expressed in relation to the
control.
E. Measurement of
Cytochrome c release
For cytochrome c
determination, cytosolic fraction was obtained by differential centrifugation.
Cytochrome c was detected by western blotting as described earlier (Sharma et
al, 2005). Staurosporine treated HeLa cells were used as a positive control for
cytochrome c release.
F. Caspase-3, -8 and
-9 activity assay
Caspase-3, -8, -9 were
measured by the direct assay for caspase enzyme activity in the cell lysate
using synthetic fluorogenic substrate (Ac-DEVD-AMC; substrate for caspase-3;
Pharmingen, Germany; Ac-LETD-AFC, substrate for caspase-8 and Ac-LEHD-AFC,
substrate for caspase-9; Genotech, USA) as described by the manufacturer.
Briefly, the cells were washed with PBS and lysed in lysis buffer on ice for 20
min. Aliquots of cell lysate (50-100μl) were then added to reaction buffer
along with 250 μM fluorogenic substrate) and incubated for 1 hr at
37oC. Amounts of fluorogenic AMC/AFC moiety released was measured
using a spectrofluorimeter (ex.380nm, em.420-460nm for Caspase-3; ex.400nm,
em.490-520nm for Caspase-8 & -9). The results were expressed as Arbitrary
Fluorescence Units/mg protein (Sen et al, 2005).
G. Statistical analysis
Statistical analysis of the samples was
done using the SAS software. Paired t-test was used to analyze the difference
in the parameters between control and various treatments. A ÔpÕ value of less
than 0.05 was considered to be statistically significant.
To explore the cytotoxicity of tiazofurin,
we started our study with the cell viability assay to determine the IC50
value in SiHa, Hep2 and Ca Ski cells. Figure 1 shows the dose response study in SiHa,
Hep2 and Ca Ski cells that were treated with various concentrations of TR for a
period of 24 hours. The IC50 value of TR was found to be 100μM
for SiHa and Hep2 whereas this value was found to be 150μM in the case of
Ca Ski cells. TR at its respective dose for different cell lines, induced
apoptotic features in all the three cell lines as revealed by light microscopy
(Figure 2).
Figure 1. Cell
viability of SiHa, Hep2 and Ca Ski cells as measured by MTT
(3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide) assay. TR:
Tiazofurin. The results are the mean ± SE of three different experiments.
Figure 2. Morphological
changes in a) SiHa, b) Hep2 and c) Ca Ski cells as revealed by light
microscopy. The photographs are of native, unstained cells, taken under an
inverted microscope (200X).
Besides the morphological changes, apoptosis was also quantitated
by measuring the sub-diploid population of cells by flowcytometry. TR treated
cells showed 34.93%, 49.67% and 31.23% apoptosis in SiHa, Hep2 and Ca Ski
cells, respectively (Figure 3).
A. Tiazofurin downregulated Bcl-2 and Bcl-xL expression
without affecting Bax expression level
Since the anti-apoptotic and pro-apoptotic
proteins are important regulators of apoptosis, therefore we analyzed their
expression in treated as well as control cells. We found that TR downregulated
the expression of the anti-apoptotic protein Bcl-2 by 1.33, 1.49 and 1.75 fold
and Bcl-xL by 1.69, 2.04and 1.32 fold in SiHa, Hep2 and Ca Ski cells
respectively as seen by Western blotting. However, no significant change in the
expression level of Bax was observed in all the three cell lines (Figure
4a,b,c).
B. Tiazofurin treatment upregulated p53 expression,
whereas it had no effect on AIF levels
An increase of 2.33, 1.71 and 1.54 fold in
p53 protein level was observed in TR treated SiHa, Hep2 and Ca Ski cells
respectively (Figure 4d),
whereas no significant difference was observed in AIF levels after TR treatment
in the respective cell lines as observed by Western blotting (Figure 4e).
C. Mitochondrial involvement
An increase of 1.52, 1.81 and 1.7 fold in
cytochrome c level was seen in cytosolic extracts after TR treatment in SiHa,
Hep2 and Ca Ski cells respectively (Figure 4f) suggesting the involvement of
mitochondria in TR-induced apoptosis.
D. PARP cleavage
Since PARP cleavage is one of the
biochemical hallmarks of apoptosis, we investigated this cleavage in our study
and measured it by western blotting. After TR treatment, a 1.47, 2.04 and 1.4
fold decrease was seen in PARP 116 KDa band in SiHa, Hep2 and Ca Ski cells
respectively (Figure 4g).
E. TR increased caspase-3 and caspase-9 activity
Since caspases are the key
players in apoptotic cascade we investigated the effect of TR on initiator and
the effector caspases. TR causes 3.09, 3.62 and 2.52 fold increase in caspase-3
activity in SiHa, Hep2 and Ca Ski cells whereas an increase of 1.81, 2.61 and
1.69 fold in Caspase-9 activity was seen after TR treatment in the respective
cell lines. However, no significant increase in caspase-8 level was seen after
TR treatment in all the three cell lines (Figure 5).
Figure 3. Percentage apoptosis in a) SiHa b) Hep2 and c) Ca Ski as
observed by flowcytometry.
Figure 4.
Densitometric analysis of protein expression of a) Bcl-2, b) Bcl-xL, c) Bax, d) p53, e) AIF, f) cytochrome c (cytosolic fraction) and g) PARP in control and treated cells as
measured by western blot analysis. The bars represent the mean of three
independent experiments± S.D. (*) indicates the statistical significance (p
<0.05).
Figure 5. Caspase-3,
-8, and –9 activity assays in SiHa, Hep2 and Ca Ski cells.
Apoptosis is a tightly controlled
multistep mechanism of cell suicide. It is critical in many physiological and
pathological contexts. In pathological states, while a failure to undergo
apoptosis may cause abnormal cell outgrowth and malignancy, excessive apoptosis
may contribute to organ injury (Tatton and Olanow, 1999; Lowe and Lin, 2000;
Strasser et al, 2000). Tumor cells often evade apoptosis by expressing several
anti-apoptotic proteins, downregulation of pro-apoptotic genes and alteration
in signaling pathways thereby restricting therapy induced apoptosis. Thus
insights into apoptotic mechanism and the factors that affect them is critical
to design more potent, specific and effective cancer therapies.
TR, a purine nucleoside analogue with the
potential for use in cancer therapy has been demonstrated to exhibit dual
mechanism of action (Grusch et al, 1999). One involves the inhibition of IMPDH,
the rate limiting enzyme for GTP and dGTP synthesis that plays a major role in
DNA synthesis, cell proliferation and regulation, and the other causes the
induction of apoptosis (Novotny et al, 2002). In the present study we analyzed
the apoptotic signaling mechanism induced by TR in SiHa, Hep2 and Ca Ski cells.
Mitochondria plays an important role in
the regulation of cell death. For example, anti-apoptotic members of the Bcl-2
family of proteins, such as Bcl-2 and Bcl-xL, are located in the outer
mitochondrial membrane and act to promote cell survival. Many of the
pro-apoptotic members of the Bcl-2 family, such as Bad and Bax also mediate
their effects though the mitochondria, either by interacting with Bcl-2 and
Bcl-xL, or through direct interactions with the mitochondrial membrane. In the
present study it seems that the observed downregulation of Bcl-2 and Bcl-xL was
sufficient to cause cytochrome c release from the mitochondria, as there was no
significant change in the protein expression level of Bax. In conjunction with
our study there are several reports in the literature that have shown that apoptosis
is induced without causing any change in Bax protein level in cerebellar
granule cells (CGCs), human colorectal carcinoma (RKO) cells and in human
non-small lung cancer (H520) cells (Gorman et al, 1999; Ji et al, 2001; Khanna
et al, 2004).
In our study, TR induced caspase-9
activation followed by activation of downstream effector caspase-3, whereas
only a limited, non-significant increase in caspase-8 was observed in all the
three cell lines. Hence it appears that TR induces apoptosis via the mitochondrial
pathway followed by caspase-3 activation and this activation was followed by
cleavage of its substrate poly (ADP-ribose) polymerase (PARP), an enzyme
involved in short-patch base excision repair. This PARP cleavage by TR in our
study is contrary to a report where TR has been reported to exhibit PARP
inhibitory effect (Yalowitz et al, 2002). But similar to our findings there are
reports in which IMPDH inhibitors have been shown to cause PARP cleavage in
human ovarian carcinoma cell lines (Grusch et al, 1999; Hunakova et al, 2000).
Moreover our results clearly demonstrate that caspase-8 is not a requirement
for TR induced apoptosis in SiHa, Hep2 and Ca Ski cells. Also a non-significant
difference in the protein expression level of AIF was observed in untreated and
treated cells therefore ruling out the possibility of involvement of this
protein in TR induced apoptosis. It appears to execute apoptosis via the
non-receptor mediated caspase activation which is dependent on p53, as we
observed a significant increase in p53 expression levels in all the three cell
lines. Also there was a significant increase in cytochrome c after TR
treatments, which further supports the involvement of mitochondria in TR
induced apoptotic signaling pathway. Similar to our findings, the IMPDH
inhibitor TR has been shown to induce apoptosis in various leukemic and human
colon carcinoma cell lines (Yalowitz et al, 2002; Colovic et al, 2003; De Abreu
et al, 2003; Wright et al, 2004). It selectively inhibits tumor cell growth and
induces apoptosis in various human tumor cell lines. IMPDH inhibitors are
biochemically convenient in inhibiting parallel pathways, thus their antitumor
potential is particularly high.
In conclusion, our results indicate that
TR induces apoptosis via the intrinsic mitochondrial pathway in SiHa, Hep2 and
Ca Ski cells. Also, the downregulation of anti-apoptotic proteins such as Bcl-2
and Bcl-xL and the upregulation of p53 which accompanied with activation of
initiator as well as effector caspases-9, -3 by TR suggest its potential
usefulness as a therapeutic for cancer treatment.
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