Antitumor effect of Bothrops
jararaca venom

Reinaldo J. da Silva1, Márcia G. da Silva2,
L ṍ zia C. Vilela2 and Denise Fecchio2,CA

1Departamento de Parasitologia, Instituto de
Biociências, and 2Departamento de Patologia,
Faculdade de Medicina, Universidade Estadual
Paulista – UNESP, Botucatu, São Paulo CEP
18618–000, Brasil

CACorresponding Author
Tel: +55 14 68026146
E-mail: dfecchio@fmb.unesp.br.

MANY experimental studies have been carried out using
snake venoms for the treatment of animal tumors,
with controversial results. While some authors have
reported an antitumor effect of treatment with specific
snake venom fractions, others have reported no
effects after this treatment. The aim of this study was to
evaluate the effect of Bothrops jararaca venom (BjV)
on Ehrlich ascites tumor (EAT) cells in vivo and in
vitro. In the in vivo study, Swiss mice were inoculated
with EAT cells by the intraperitoneal (i.p.) route and
treated with BjV venom (0.4 mg/kg, i.p.), on the 1st,
4th, 7th, 10th, and 13th days. Mice were evaluated for
total and differential cells number on the 2nd, 5th, 8th,
11th and 14th days. The survival time was also
evaluated after 60 days of tumor growth. In the in vitro
study, EAT and normal peritoneal cells were cultivated
in the presence of different BjV concentrations (2.5,
5.0, 10.0, 20.0, 40.0, and 80 mg) and viability was
verified after 3, 6, 12 and 24 h of cultivation. Results
were analyzed statistically by the Kruskal–Wallis and
Tukey tests at the 5% level of significance. It was
observed that in vivo treatment with BjV induced
tumor growth inhibition, increased animal survival
time, decreased mortality, increased the influx of
polymorphonuclear leukocytes on the early stages of
tumor growth, and did not affect the mononuclear
cells number. In vitro treatment with BjV produced a
dose-dependent toxic effect on EAT and peritoneal
cells, with higher effects against peritoneal cells.
Taken together, our results demonstrate that BjV has
an important antitumor effect. This is the first report
showing this in vivo effect for this venom.

Key words: Antitumor effect, Ehrlich ascites tumor,
Bothrops jararaca, Venom

Introduction

Many experimental studies have been carried out
using snake venoms for the treatment of animal
tumors. However, we have seen many controversies
on this subject. Some authors have reported that
tumor treatment with specific snake venom fractions
has an important toxic effect on tumor cells, while
others have reported no antitumor effects after
inoculation with snake venoms.1

The exact mechanisms that cause tumor regression
in experimental animals after treatment with crude
snake venom and/or any fraction of this venom still
are unknown.1 According to Lipps,2 certain fractions
isolated from snake venoms revealed a direct cytolytic
activity on tumor cells. Markland,3 on conducting
research on crotalase, proposed that malignant cells
would produce a microenvironment around them,
using substances of the host itself that protected them
against defensive responses of the immune system.
This microenvironment would be composed of fibrin

deposits from the nearby blood vessels. Crotalase
apparently destroyed the microenviroment produced
by the tumor cells attacking fibrinogen directly, which
led to the formation of soluble fibrin monomers, or
abnormal fibrin microclots, that were rapidly
removed by secondary activation of the fibrinolytic
system. Thus, immunological masking would not have
occurred, which would leave tumor cells unpro-
tected. The literature demonstrates also that snake
venoms may induce apoptosis in both normal and
tumor cells.4–12 In most of these works, the proposed
apoptosis induction mechanism was H2O2 production
induced by the venom enzyme L-amino acid oxidase.
This enzyme was purified from Crotalus adamanteus
venom and its structure showed a high degree of
homology with murine interleukin-4.13

However, it has been demonstrated that continuous
contact of venom and tumor cells was necessary to
obtain an antitumor effect. Yoshikura et al.14 eval-
uated the effects of Trimeresurus flavoviridis crude
venom and the hemorrhagic principles in different

ISSN 0962-9351 print/ISSN 1466-1861 online/02/020099-06 © 2002 Taylor & Francis Ltd 99
DOI: 10.1080/09629350220131953

Research Communication

Mediators of Inflammation, 11, 99–104 (2002)



cell strains in vitro.They demonstrated that treatment
caused morphological and physiological alterations in
tumor cells without causing cellular death. However,
when these altered cells were removed from the
venom-containing medium and placed in a venom-
free culture medium, they showed normal morphol-
ogy and physiology and grew in the medium. Leung et
al.15 corroborated this and reported that the cardio-
toxin from Naja sp. venom shows a cytolytic effect
on Ehrlich ascites tumors cells and that cytolysis
progression required continuous venom presence.
This cytolytic activity completely stopped if the toxin
was removed from the medium.

It can be considered that antitumor effects of snake
venoms depend on the venom biodistribution time.
Tanigawa et al.16 demonstrated that jararafibrase-I and
jararafibrase-II, two fibrinolytic/hemorrhagic enzymes
of Bothrops jararaca venom (BjV), show rapid
biodistribution in the body. Five minutes after intra-
venous inoculation in mice, its concentration in blood
decreases by 60%. Similarly, Thwin et al.17 showed
that Vipera russeli venom inoculated intravenously in
mice was rapidly eliminated in urine.

The literature shows that mononuclear (MN) leu-
kocytes may effectively participate in tumor cell
elimination.18–26 A previous study27 evaluated the
percentage of macrophage spreading and found that,
after treatment with Crotalus durissus terrificus
venom, they were quite spread out with increases in
size and presence of large cytoplasmatic vacuoles,
suggesting high cellular activity. This increase was
not observed in non-venom groups. However, Rabi-
novitch and Destefano28 demonstrated that proteo-
lytic enzymes may induce macrophage spreading as
they are capable of removing macromolecular com-
ponents from the cell surface and affecting macro-
phage surface receptors, resulting in a higher affinity
of the cell membrane to the substrate. This suggests
that although an increase in macrophage spreading
percentage has been observed,27 this may not lead
to an increase in the functional activity of these
cells.

Most studies report on different snake venoms,
mainly Crotalus spp. and Naja spp.1 There was only
one study with BjV, which reports a cytophatic
effect on normal and tumor cells in vitro.29 The in
vivo antitumor effect of this venom was not studied.
The objective of the present paper is to evaluate the
antitumor effect of BjV on tumor cells in vivo and
in vitro.

Materials and methods

Animals

Swiss strain male mice, 4–6 weeks old, from our
own animal facilities were used throughout the
experiment.

Venoms

BjV was obtained from snakes maintained in captivity
at The Center for the Study of Venoms and Venomous
Animals of São Paulo State University, Brazil. Newly
extracted venom was centrifuged for 10 min at
1500 rpm, filtered using a GSWP00250 Millipore filter
and then lyophilized. The lethal dose 50 (LD50) for
this venom has been previously determined as
2.4 mg/kg of animal weight. The venom was stored at
4°C during the experiment. Preliminary protocols
shown that 0.4 mg/kg BjV was efficient for tumor
growth inhibition.

Ehrlich ascites tumor

The tumor was maintained in Swiss mice in the ascitic
form. Tumor cells were collected by aspiration with a
Pasteur pipette, centrifuged for 10 min at 200 ́ g, and
washed twice with phosphate-buffered saline (PBS)
(pH 7.2). Cell viability was evaluated by the trypan
blue exclusion test, and only cell suspensions that
presented more than 95% viability were used.

Peritoneal cells

Cells were harvested by peritoneal washing using
3 ml of sterile PBS. The number of cells was deter-
mined using a hemacytometer. Differential counts
were performed on fixed and stained cell suspensions
(0.5% crystal violet dissolved in 30% acetic acid).

In vivo experiment

Mice were inoculated by the intraperitoneal route
(i.p.) with 1 ´ 103 Ehrlich ascites tumor (EAT) cells
and treated with BjV (0.4 mg/kg) or saline (0.1 ml,
i.p.). The first BjV dose was administered 24 h after
tumor implantation and repeated five times in each
72-h interval. Additional control groups with no
tumor bearing were treated with BjV or saline, in the
same protocol of experimental groups. After 2, 5, 8,
11, and 14 days of EAT implantation, 10 animals from
each group were sacrificed in a sulfur ether chamber,
and peritoneal cells were analyzed for tumor, poly-
morphonuclear (PMN), and MN cell numbers. The
remaining 10 animals from each group were kept in
the laboratory for 60 days for survival analysis. These
procedures were repeated twice and data were
grouped for statistical analysis.

In vitro experiment

EAT and peritoneal cells were cultivated with 0
(control), 2.5, 5, 10, 20, 40, and 80 mg of BjV.
Peritoneal washing was performed on mice inocu-
lated with EAT cells and on normal mice. Cellular
suspensions adjusted to 1 ́ 103 EAT cells and 5 ́ 103

R. J. da Silva et al.

100 Mediators of Inflammation · Vol 11 · 2002



peritoneal cells were cultivated in RPMI medium
supplemented with 5% fetal bovine serum for 24 h at
37°C and 5% CO2 atmosphere. The cultures were then
washed and the cells placed in RPMI medium
containing BjV at different doses. After 3, 6, 12, and
24 h, cell viabilities were analyzed. These procedures
were repeated twice and data were grouped for
statistical analysis.

Statistical analysis

Data were analyzed by the Kruskall–Wallis or analysis
of variance tests for independent sets, and by the Tukey
or Student–Newman–Keuls tests for differences
between the groups. The significance level was 5%.

Results

In vivo experiment

Animals inoculated with EAT cells and treated with
saline (G3) presented exponential growth of tumor
cells after the 8th day, with a total number of 70 ́ 106

cells/ml at the 14th day. In the animals of the group
inoculated with EAT cells and treated with BjV (G4),
a significant reduction in tumor cells was observed on
the 11th and 14th days; the final number was 0.7 ´
106 cells/ml (Fig. 1).

PMN leukocytes influx in animals inoculated with
EAT (G3) showed significant influx of these cells on
the 8th, 11th, and 14th days. Animals inoculated with
EAT cells and treated with BjV (G4) showed a
significant increase throughout the study. PMN leuko-
cyte influx was also observed in non-tumor-bearing
animals treated with BjV (G2), the BjV only group
(Fig. 2).

In addition, animals inoculated with EAT cells and/
or BjV (G2, G3, and G4) showed a significant influx in
MN leukocytes throughout the study (Fig. 3).

Survival analysis revealed that the animals inocu-
lated with EAT cells and treated with BjV have
increased survival times and decreased mortality,
compared with untreated animals (Fig. 4).

In vitro experiment

All tested venom concentrations showed a toxic effect
on tumor cells. We observed higher toxicity when the
higher doses of BjV were used, and vice versa. We have
also observed that, for concentrations of 2.5, 5, and
10 mg, there was a mean increase in cell viability at 6 h
in comparison with 3 h. This increase was not seen
with concentrations of 20, 40, and 80 mg (Fig. 5).

Similar to the tumor cells, all the tested venom
concentrations showed a toxic effect on mice perito-
neal cells, with higher toxicity associated with
treatment with higher doses of venom (Fig. 6).

Antitumor effect of BjV

Mediators of Inflammation · Vol 11 · 2002 101

FIG. 1. Distribution of the median of the number of EAT cells
on the 2nd, 5th, 8th, 11th, and 14th days of tumor growth.
Each box represents 25–75% values, with the median as an
internal line; the error bar represents the percentiles 10 and
90, and the circle represents the outliers. Statistics: 11th and
14th days, G3 > G4; p < 0.05.

FIG. 2. Distribution of the median of the number of PMN cells
on the 2nd, 5th, 8th, 11th, and 14th days of tumor growth.
Each box represents 25–75% values, with the median as an
internal line; the error bar represents the percentiles 10 and
90, and the circle represents the outliers. Statistics: 2nd day,
G2 = G4 > G1 = G3; 5th day, G4 > G1 = G3; 8th, 11th, and 14th
days, (G2 = G3 = G4) > G1; p < 0.05.

FIG. 3. Distribution of the median of the number of MN cells
on the 2nd, 5th, 8th, 11th, and 14th days of tumor growth.
Each box represents 25–75% values, with the median as an
internal line; the error bar represents the percentiles 10 and
90, and the circle represents the outliers. Statistics: 11th and
14th days, (G2 = G3 = G4) > G1; p < 0.05.



The comparative in vitro evaluation showed a
peritoneal cell viability rate significantly higher than
tumor cells after 3 h culture at 2.5, 5, and 10 mg
venom. At 20 mg, although the tumor cell mean
viability rate was higher than peritoneal cells, it was
not statistically significant. At concentrations of 40
and 80 mg, the tumor cells showed significantly
higher viability than the peritoneal cells. After 6 h
culture at 2.5 and 5 mg, we observed no significant
difference between tumor and peritoneal cells. At 10,
20, 40, and 80 mg, however, tumor cell viability was
significantly higher than peritoneal cells. At 12 h, only
the 2.5 mg concentration showed no significant differ-
ence. For all the other concentrations (5, 10, 20, 40,
and 80 mg), tumor cell viability was higher than the
normal cells. At the end of the experiment (24 h),
viability of tumor cells was higher than normal cells at
all venom concentrations (Figs 5 and 6).

Discussion

This study evaluated the effect of BjV treatment on
the kinetics of tumor growth, inflammatory influx,
and animal survival in vivo, and on its toxic and/or
mitotic effect in vitro.

Analysis of total number of cells in the peritoneal
cavity shows that the number of cells in the group
that received tumor cells and venom treatment was
around 10% of that of the group with tumor cells only.
This suggests that although there was tumor growth
in the treated group, this was of lower magnitude
than in the non-treated group.

With regard to number of tumor cells, treatment
with BjV promoted 99% tumor growth inhibition.
These data show that treatment of EAT mice with
0.4 mg/kg of BjV induces major tumor growth inhibi-
tion. These results are in agreement with previous
studies evaluating the effects of BjV on tumor cells29

and others showing an antineoplastic effect asso-
ciated with snake venom treatment.30–41

Tumor growth inhibition caused by BjV was accom-
panied by inflammatory influx alterations. Treatment of
EAT animals with BjV induced a significant increase of
PMN leukocytes in the initial stages (2nd and 5th days)
in comparison with the non-treated EAT group. This
suggests that tumor growth inhibition may be related to
PMN leukocyte influx at the beginning of the experi-
ment – the beginning of tumor growth. At this stage, the
presence of PMN leukocytes, attracted to the tumor
growth site and activated by the venom either by
oxygen free radical generation42 or modulation of the
inflammatory response via tumor necrosis factor-a43,
might play a role in modifying the environment
necessary for tumor development.

With regard to MN cells, we observed an increase
of tumor growth from day 11 in all groups inoculated

R. J. da Silva et al.

102 Mediators of Inflammation · Vol 11 · 2002

FIG. 4. Survival percentage of animals inoculated with EAT
cells and treated with BjV or saline solution (* p < 0.05).

FIG. 5. Cellular viability of tumor cells after 3, 6, 12, and 24 h
of cultivation in RPMI medium at 37°C and 5% CO2, and
incubation with 2.5, 5, 10, 20, 40, and 80 mg of BjV. Each point
represents the mean and the standard error values (n = 48).
Statistics: 3 h, (G1 = G2) > (G3 = G4 = G5 = G6); (G1 = G2 = G3)
> (G4 = G5) > G6; 12 h, (G1 = G2) > G3 > G4 > G5 > G6; (G1 =
G2) > (G3 = G4 = G5) > G6; p < 0.05.

FIG. 6. Cellular viability of peritoneal cells after 3, 6, 12, and
24 h of cultivation in RPMI medium at 37°C and 5% CO2, and
incubation with 2.5, 5, 10, 20, 40, and 80 mg of BjV. Each point
represents the mean and the standard error values (n = 48).
Statistics: 3 h, G1 > (G2 = G3) > (G4 = G5) > G6; 6 h, (G1 = G2)
> G3 > G4 > G5 > G6; 12 h, G1 > (G2 = G3 = G4) > G5 > G6;
24 h, G1 > G2 > (G3 = G4) > (G5 = G6); p < 0.05.



with EAT and/or venom. This indicates that both BjV
and the presence of EAT may induce an increase in
MN cell influx. Although no difference was detected
in the quantity of MN cells in the peritoneal cavity, we
do not rule out the possibility that different sub-
populations may be involved in tumor growth inhibi-
tion.18–26 The inflammatory capacity of BjV has also
been demonstrated by the evaluation of PMN and MN
leukocyte influxes into the venom only group. This
group showed increased PMN on the 2nd, 8th, 11th
and 14th days, and increased MN on the 11th and
14th days.

Our study also evaluated the in vitro antimytotic
and/or toxic effect of BjV on EAT cells and mice
peritoneal cells. We observed that the venom showed
a toxic effect both on tumor cells and peritoneal cells,
with a higher toxicity for peritoneal cells. These
results are not in agreement with studies showing the
preferential effect of venom on tumor cells more than
normal cells,2,33 but are in agreement with work by
Rizzo and Tuchiya29 that showed the in vitro toxic
effect of BjV on HeLa, KB, and Hep-2 tumor cells, and
on normal rabbit kidney and chicken embryo cells.
These authors29 have also demonstrated that the
tumor cells were more resistant to venom than
normal cells, as seen in this study.

BjV has different actions, such as cytotoxic
action.44,45 It is possible, then, that this venom’s
proteolytic enzymes may be responsible for the death
of tumor and peritoneal cells, as suggested by
Lipps.2

However, in the in vitro cultivation conditions used
in this study, the venom remained in direct contact
with cells for 24 h. In the in vivo study, immediately
after venom inoculation, the biodistribution process
starts and it is soon eliminated from the peritoneal
cavity, as previous demonstrated.16,17 Therefore, in
contrast to the in vitro study, we can suggest that Bj
venom does not act for a long period of time on tumor
cells in vivo. Also, even in vitro at 10 mg concentra-
tion, corresponding to 0.4 mg/kg concentration in a
25 g animal, tumor cell viability after 24 h venom
contact was 56.1%. Assuming that this toxic effect
was repeated in vivo, the non-affected part (43.9%)
could still continue to multiply, leading to tumor
growth despite venom treatment. This can be seen in
the in vivo study since, for the venom-treated EAT
group, the reduction of tumor growth was not 100%.
Even after venom treatment, some animals still
showed tumor growth. A similar observation was
reported by Yoshikura et al.14 and Leung et al.15

Although the antineoplastic effect of venom treat-
ment has been observed in vivo and works on
apoptosis induction have been performed only in
vitro,4–12 we can consider that the apoptotic pro-
cesses may be involved in the growth inhibition of the
EAT. In addition, L-amino acid oxidase, the main
venom enzyme associated with apoptotic proces-

ses,13 has been described as one of the venom
components from all snakes of the Bothrops
genus,46,47 and therefore we cannot exclude the
possible action of this enzyme on EAT cells. It is
important to emphasize that, as already discussed for
the venom effect on tumor cells, venom biodistribu-
tion in the body should also be considered for
apoptosis; it would be important to demonstrate that
the venom has enough contact time with tumor cells
to induce apoptosis.

In the in vitro study, we also observed that tumor
cells were more resistant to the venom toxic effect
than peritoneal cells. We believe that in vitro induc-
tion of apoptosis may have a major role in cellular
death. As we observed a higher sensitivity from
peritoneal cells to venom, and as it is a characteristic
of this venom to induce apoptosis, we can suggest
that the peritoneal cells may be more susceptible to
the apoptotic effect of the venom than the tumor
cells.

Taken together, our results demonstrated that BjV
has an important antitumor effect. This is the first
report showing this in vivo effect for this venom.
Future studies with protein fractions of BjV may
reveal some biological product will contribute to
improve the antitumor effect.

ACKNOWLEDGEMENTS. Financial Support from the Fundação de Amparo à
Pesquisa do Estado de São Paulo (FAPESP).

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Received 27 November 2001
Accepted 4 February 2002

R. J. da Silva et al.

104 Mediators of Inflammation · Vol 11 · 2002



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