Snake Venoms in Cancer Therapy: Past, Present and Future PDF

Summary

This review article discusses the potential of snake venom in cancer treatment and target therapy. It examines the past, present, and future research, along with the key contributions in this field. The article details the application of snake venom components in different cancer therapies with their specific implications for future combinational technologies.

Full Transcript

toxins
Review
Snake Venoms in Cancer Therapy: Past, Present
and Future
Li Li 1 ID
, Jianzhong Huang 1, * and Yao Lin 2, * ID

1 Engineering Research Center of Industrial Microbiology, College of Life Sciences, Fujian Normal University,
Fuzhou 350117, China; [email protected]
2 Provincial University Key Laboratory of Cellular Stress Response and Metabolic Regulation,
College of Life Sciences, Fujian Normal University, Fuzhou 350117, China
* Correspondence: [email protected] (J.H.); [email protected] (Y.L.)




Received: 1 August 2018; Accepted: 26 August 2018; Published: 29 August 2018


Abstract: Cancer is one of the leading causes of morbidity and mortality worldwide, and the discovery
of new drugs for cancer therapy is one of the most important objectives for the pharmaceutical
industry. Snake venoms are complex mixtures containing different peptides, proteins, enzymes,
carbohydrates and other bioactive molecules, which are secreted by the snake in the predation or
defending against threats. Understanding the snake venoms may turn the toxins into a valuable
source of new lead compounds in drug discovery. Captopril, the first angiotensin-converting enzyme
inhibitor approved in 1981 by FDA, was designed based on the structure of a peptide isolated from
the snake venom. The earliest reports about snake venoms used in cancer treatments appeared
in the 1930s. Since then, numerous studies on the activities, isolations, purifications and structure
elucidations of the components from snake venoms were published. The comprehensive structural
and functional investigations of snake venoms would contribute to the development of novel
anti-cancer drugs. Our review will focus on the past, present and the future of the studies on
snake venoms in cancer target therapy.

Keywords: snake venom; cancer; target therapy

Key Contribution: In this review, the application of snake venoms and their potential future
combinational technologies for cancer therapy were thoroughly discussed.

1. Introduction
Cancer is one of the leading causes of morbidity and mortality worldwide. According to
GLOBOCAN, there were approximately 14.1 million new cases diagnosed and 8.2 million deaths
from cancer in 2012 globally. Surgery and chemotherapy are still the main strategies for cancer
therapy. Target therapy, which interferes with a specific molecular target and usually causes
fewer toxicities, is becoming more and more popular in chemotherapy [3,4]. Recently, the compounds
purified and characterized from snake venom displayed a tremendous potential as agents targeting
specific molecular pathways in cancer cells [5,6].
Snake venoms are complex mixtures of proteins, peptides and other bioactive molecules secreted
by the venom gland of snakes and injected by unique fangs of snakes to debilitate and digest their prey.
World Health Organization has placed snakebite envenoming on its list of top 20 priority neglected
tropical diseases, which kills more than 100,000 people and maims 400,000 people annually.
The various clinical manifestations of snakebite victims are caused by the highly complex and
diverse compositions of snake venoms, which can selectively recognize their different biological
targets. Although snakebite envenoming is a life-threatening public health problem, snake venoms

Toxins 2018, 10, 346; doi:10.3390/toxins10090346 www.mdpi.com/journal/toxins
Toxins 2018, 10, 346 2 of 8

are recognized as a potential resource of biologically active compounds. In China, snake wine
or snake venom liquor is supplied as traditional Chinese medicine. Snake venoms are also
discovered and developed as drug leads in the modern drug industry. For example, captopril was
the first angiotensin-converting enzyme inhibitor approved in 1981 by FDA for the treatment of
hypertension and some types of congestive heart failure. Captopril was actually designed based on
BPP5a , a bradykinin-potentiating pentapeptide isolated from venoms of Bothrops jararaca.
Common venom components could be classified as enzyme and non-enzyme components.
Enzymatic snake venoms include phospholipase A2 (PLA2 ), L-amino acid oxidases (LAAO),
metalloproteases (SVMP), serine proteases (SVSP), 50 -nucleotidases, acetylcholinesterases and
hyaluronidases. Non-enzymatic components include disintegrins (DIS), three-finger toxins (3FTx),
Kunitz peptides, cysteine-rich secretory proteins (CRiSP), C-type lectins (CTL) and natriuretic peptides
(NP). There has been a long history of research on exploring the therapeutic potential of snake
venoms for cancer.

2. Early-Stage Study on Snake Venoms in Cancer Therapy
The effect of snake venoms was first investigated in the 1930s. For example, Essex et al. treated
15 tumor-bearing white rats with intravenous injections of different doses of venoms from rattlesnakes.
However, after 6 successive weeks, cancer progresses between the experimental and control groups
were similar. Kurotchkin et al. discovered that cobra venom could destroy cells of the Fujinami rat
sarcoma, which seemed to require direct contact between the venom and tumor cells. Ligneris et al.
showed that African snake venoms had no effect on the great majority of tumors in humans.
Notwithstanding, there were no encouraging results on cancer suppression, the pain relief effects
of snake venoms were shown in some cases, whose advantages were long-acting and no morphine
dependence. In 1936, Macht reported the experimental and clinical study of cobra venoms as
pain-relieving agents. In total, 105 cancer patients were injected with a dose of 2–5 mouse units,
which was defined as the quantity of venom solution enough to kill a 22 g white mouse within 18 h
after intraperitoneal injection. Among the patients, 30 cases showed definite relief and 38 cases
showed marked relief. Only 13.3% of the patients showed doubtful results or no relief.
Meanwhile, enzymes of snake venoms attracted attention of investigators for their potent
biological significances. In 1938, Jynegar et al. found the activity of cholinesterase in cobra venom ,
and Zeller found that cholinesterase exists in many types of snake venom. The activity of
hyaluronidase in snake venom was noted by Duran-Reynals in 1936. The first nonhydrolytic
enzyme, L-amino acid oxidase (LAAO), was reported by Zeller in 1944.
In summary, the studies on the inhibitory effect of crude snake venoms towards tumor cells
showed doubtful results at the early stages. The snake venom was used as the mixture and their main
clinical effect for cancer therapy was pain relief for the patients with hopelessly malignant tumors.

3. Development of Snake Venoms for Cancer Target Therapy
The isolation and characterization of the components from snake venoms began in the 1940s.
After that, numerous components including enzymes, non-enzyme proteins and peptides were
purified, sequenced and structurally elucidated. L-amino acid oxidase (LAAO) was first isolated
and characterized by Singer et al. from moccasin snake venom in the early 1950s [21–24]. LAAO is
a FAD (Flavin Adenine Dinucleotide)—containing an enzyme that converts L-amino acid stereospecific
into the corresponding α-keto acid with hydrogen peroxide and ammonia as byproducts.
Phospholipase A2 (PLA2 ) from Crotalus adamanteus was purified and partially characterized
by Saito and Hanahan in 1962. In 1969, Wu and Tinker studied PLA2 from Crotalus atrox.
The PLA2 enzyme hydrolyzes glycerophospholipid to form lysophopholipid and fatty acid. Snake
venoms often contain multiple types of PLA2 isoenzymes, resulting in extra difficulty for purification.
For example, eight PLA2 (Pa-1G, Pa-3, Pa-5, Pa-9C, Pa-10A, Pa-12A, Pa-12C and Pa-15) have been
isolated and sequenced from the venom of Australian king brown snake (Pseudechis australis).
Toxins 2018, 10, 346 3 of 8

The lectin-related proteins in snake venom have been classified into true C-type lectins (containing
the CRD domain) and C-type lectin-like proteins (containing the CRD-related non-carbohydrate-
binding domains) [29,30]. A slice of C-type lectins or C-type lectin-like proteins were isolated from
snake venoms in 1970s. Batroxobin, a lectin from Bothrops atrox venom, was isolated by Stocker and
Barlow in 1976. Kirby et al. purified and characterized thrombocytin from B. atrox venom in
1979. It was found that C-type lectin binds to a sugar moiety at the presence of Ca2+ and contains
the carbohydrate recognition domain (CRD).
Snake venom metalloproteinase (SVMP) is a major component in most viperidvenoms, and one
of the import enzymes contributing to the toxicity of snake venom. In 1978, Bjarnason and Tu
purified SVMPs from western diamondback rattlesnake (Crotalus atrox) venom and showed that the
zinc in each of these SVMPs was at approximate 1:1 ratio to the relevant protein. Removal of zinc from
SVMPs abolished both proteolytic and hemorrhagic activities of the SVMPs.
Disintegrins are a family of integrin inhibitory proteins with low molecular weight, tripeptide
sequence arginine-glycine-aspartic acid (RGD), and cysteine-rich peptides isolated from various
snake venoms. The integrin binding function usually depends upon the RGD motif. However,
some disintegrins lacking this RGD motif can also bind and block integrins. In the late 1980s,
Huang et al. purified and determined the primary structure of trigramin, a disintegrin from
Trimeresurus gramineus snake venom, which kicked off a promising research field of the inhibition of
integrin function by snake venom [36–38]. The isolation and characterization of components of snake
venoms paved the way for cancer targeted therapy in modern medicine. Here, we discuss the army of
snake venoms with different mechanisms of actions in cancer therapy (Table 1).

Table 1. Compounds with antitumor activities isolated from snake venoms.

Target/Mechanism Protein Names Compounds Snakes Reference
Leucurogin disintegrin Bothrops leucurus
Contortrostatin disintegrin Agkistrodon contortrix contortrix
antiangiogenesis Obtustatin disintegrin Vipera lebetina obtusa
Adinbitor disintegrin A. halys brevicaudus stejneger [42,43]
Salmosin disintegrin A. halys brevicaudus
LAAO LAAO A. halys [45,46]
AHP-LAAO LAAO A. halys pallas
apoptosis LAAO LAAO V. berus berus
induction disintegrin disintegrin Naja naja
VAP and VAP2 metalloprotease/disintegrin Crotalus atrox [50,51]
stejnitin SVMP Trimeresurus stejnegeri

3.1. Antiangiogenesis
Human tumor growth is accompanied by neovascularization to provide essential nutrition
and oxygen. Angiogenesis supports tumor cell extension and invasion into nearby normal tissue
and is required to distant metastasis. Antiangiogenesis is a propitious strategy for cancer targeted
therapy. Quite a few angiogenesis inhibitors for the treatment of cancer have been approved by FDA
including Bevacizumab (targeting vascular endothelial growth factor, VEGF), Sorafenib (tyrosine
kinase inhibitror, TKI), Sunitinib (TKI) et al..
Disintegrins purified from snake venoms showed antiangiogenesis effects. Leucurogin, a disintegrin
cloned from Bothrops leucurus (white-tailed-jararaca), showed significant anticancer activities against
Ehrlich tumor implanted in mice with the administration of 10 µg/day. Antiangiogenesis effect of
leucurogin was assessed and confirmed by the sponge implant model in mice. Contortrostatin
is a homodimeric peptide isolated from the venom of Agkistrodon contortrix contortrix, a subspecies
of the southern copperhead snake, and contains a RGD sequence. Contortrostatin showed
anti-angiogenic activity against the primary tumor of human breast cancer MDA-MB-435 carried
in mice. Obtustatin, a disintegrin isolated from Vipera lebetina obtusa venom has no classical RGD
sequence. Obtustatin reduced tumor size in the Lewis lung syngeneic mouse model and showed
Toxins 2018, 10, 346 4 of 8

84% inhibition of angiogenesis activities in the experiments of chick Chorioallantoic Membrane
(CAM) assay. Adinbitor is a disintegrin cloned from Agkistrodon halys brevicaudus stejneger with
73 amino acid residues including 12 cysteines and a RGD motif. Adinbitor can inhibit bFGF-induced
proliferation of ECV304 cells with IC50 of 0.89 µM. In the Chick CAM angiogenesis assay, adinbitor
showed the activities against bFGF-induced angiogenesis both in vivo and in vitro [42,43]. Salmosin
was purified from the snake venom of Agkistrodon halys brevicaudus in 1998. Salmosin can prevent
the bFGF induced bovine capillary endothelial cell proliferation. Treatment with salmosin significantly
suppressed the growth of both the metastatic and solid tumor in mouse xenografts of Lewis lung
carcinoma cells, and the tumor specific antiangiogenic activity of salmosin was considered related to
the blockade of αv β3 integrin.

3.2. Apoptosis Induction
Apoptosis is a process of programmed cell death to delete unnecessary cells in normal tissues and
to keep cellular homeostasis. Any critical defect in the apoptotic process may lead to uncontrolled
growth of cells and result in cancer [56,57]. A subset of snake venom proteins have demonstrated
antitumoral activities by inducing apoptosis. In 1993, Araki et al. found that some hemorrhagic
snake venoms induced apoptosis of vascular endothelial cells. However, the active component was
unknown. After the report of Araki et al., increasing LAAOs from snake venoms have increasingly
been shown to induce apoptosis. Suhr and Kim purified and characterized a LAAO from the venom of
Agkistrodon halys, and exposure to this LAAO resulted in the apoptosis of cultured L1210 cells.
Later, the research of Suhr et al. suggested that the activity of apoptosis induction of LAAO was not
solely due to the production of H2 O2 in the reaction of LAAO.
AHP-LAAO, a novel snake-venom LAAO, was isolated from A. halys pallas venom in 2004.
The AHP-LAAO inhibited the proliferation of HeLa cells at 0.5 µg/mL and induced DNA
fragmentation and nuclear morphological changes. Samel et al. purified and characterized
a homodimer LAAO from the venom of the common viper Vipera berus berus. The DNA fragmentation
gel pattern indicated that the LAAO from V. berus berus induced apoptosis in cultured K562 and
HeLa cells, and the inhibition of apoptosis by catalase suggested the role of hydrogen peroxide in the
process.
Not only LAAO but also some disintegrins showed the activities of apoptosis induction.
Thangam et al. purified the disintegrin from the venom of the Indian cobra snake (Naja naja),
whose anticancer activity was at IC50 of 2.5 ± 0.5 µg/mL, 3.5 ± 0.5 µg/mL, and 3 ± 0.5 µg/mL
for the MCF-7, A549 and HepG2 cell lines respectively. The DNA fragment analysis and AO/EtBr
staining assay suggested that this disintegrin induced the apoptosis of the cancer cell lines.
Two metalloprotease/disintegrin family proteins, VAP and VAP2, were purified from the venom of the
rattlesnake Crotalus atrox. The apoptosis-inducing activities seemed to be specific towards endothelial
cells [50,51]. Han et al. characterized stejnitin, a SVMP from the venom of Trimeresurus stejnegeri.
Stejnitin comprises metalloproteinase and disintegrin, and the DNA fragmentation and flow cytometry
analysis suggested stejnitin induces apoptosis in ECV304 cells.

4. Future Directions
Though there was an ample evidence about the therapeutic potentials of snake venoms in the
treatment of cancer, more research is needed. Most components of snake venoms, including PLA2 s,
LAAOs, metalloproteases, disintegrins and other peptides show cytotoxicity to cancer cells. However,
the discrimination between normal and cancer cells is the main problem in cancer treatment.
From our perspective, future research could pour more attention into these actions (Figure 1).
Toxins 2018, 10, 346 5 of 8

4.1. Isolation and Characterization of New Active Molecules from Snake Venoms by Snake Venomics
One of the major barriers in exploring snake venom is the low amount isolated from the venom
glands, especially of rare snakes. The snake venomics will increase the discovery of the snake venom
proteins and peptides for the development of new drugs for potential use.
Toxins 2018, 10, x FOR PEER REVIEW 5 of 8
4.2. New Drug Delivery System/Coupled with Monoclonal Antibody
4.2.
OneNew Drug
of the Delivery strategies
plausible System/Coupled with Monoclonal
to develop Antibody versions of cytotoxins is to conjugate
clinical anti-cancer
the drugsOne withofmonoclonal antibodies
the plausible strategiesthat
to recognize and bind
develop clinical to specific
anti-cancer epitopes
versions of on malignant
cytotoxins cancer
is to
cells.conjugate
As an example, Zhao
the drugs with etmonoclonal
al. used an antibodies
anti-nasopharyngeal
that recognizecarcinoma
and bindmonoclonal antibodyon
to specific epitopes BAC5
malignant
conjugated withcancer cells. of
the venom AstheanChinese
example, Zhaowhich
cobra, et al.showed
used an anti-nasopharyngeal
strong carcinoma
effects against nasopharyngeal
monoclonal
carcinoma cells antibody BAC5 conjugated with the venom of the Chinese cobra, which showed strong
in vitro.
effects against nasopharyngeal
The other method for targeted carcinoma cells in vitro
cancer therapy.
by cytotoxin from snake venom is to combine the
The other method for targeted cancer therapy by
snake venom with silica nanoparticles. Al-Sadoon et al. demonstrated cytotoxin from snake
thatvenom is tovenom
the snake combine the
extracted
snake venom with silica nanoparticles. Al-Sadoon et al. demonstrated that the snake venom extracted
from Walterinnesia aegyptia (WEV) combined with silica nanoparticles (NP) can inhibit the proliferation
from Walterinnesia aegyptia (WEV) combined with silica nanoparticles (NP) can inhibit the
of human breast carcinoma cell lines and strongly induced apoptosis without significant effects on
proliferation of human breast carcinoma cell lines and strongly induced apoptosis without significant
normal breast
effects epithelial
on normal MCF-10A
breast epithelialcells. Al-Sadoon
MCF-10A et al. alsoetevaluated
cells. Al-Sadoon the effects
al. also evaluated of WEV+NP
the effects of
in the therapy of multiple myeloma in the nude mouse model. WEV+NP
WEV+NP in the therapy of multiple myeloma in the nude mouse model. WEV+NP showed greater showed greater activities
thanactivities
WEV alone than in decreasing
WEV the surface
alone in decreasing theexpression of the chemokine
surface expression receptors
of the chemokine CXCR3,
receptors CXCR4
CXCR3,
and CXCR4
CXCR6 and and CXCR6
decreased
andmigration
decreased of the cancer
migration of cells , suggesting
the cancer this approach
cells , suggesting this possesses
approach the
possesses
promising the promising
therapeutic therapeutic
potential potential
for clinical for clinical
application ofapplication of snake venoms.
snake venoms.

Figure
Figure 1. 1.Effective
Effective targeting
targeting therapy
therapybybycytotoxins of snake
cytotoxins venoms
of snake with new
venoms withapproaches. (A):
new approaches.
Nanoparticles transport snake venoms to specific locations in the body; (B): Snake venoms conjugated
(A): Nanoparticles transport snake venoms to specific locations in the body; (B): Snake venoms
with monoclonal antibodies for targeted therapy.
conjugated with monoclonal antibodies for targeted therapy.
5. Conclusions
5. Conclusions
In conclusion, the application of the snake venoms in cancer therapy has evolved from the usage
In the
of conclusion, the application
crude mixtures of the
in the 1930s snake
into the venoms
isolationinofcancer
certaintherapy has evolved
biologically from the usage
active components
of the crude mixtures in the 1930s into the isolation of certain biologically active
targeting specific molecular pathways. Currently, the combination of snake venoms with other components targeting
specific molecular
technologies pathways.
such Currently,
as nanoparticles is stillthe combination
at its of cancer
early stage for snake therapy
venomsand with other
it can be technologies
expected
suchthat more combinational
as nanoparticles treatment
is still will stage
at its early emerge. forSnake venoms
cancer are no
therapy anddoubt valuable
it can resources
be expected formore
that
cancer drug treatment
combinational development.will emerge. Snake venoms are no doubt valuable resources for cancer
drug development.
Funding: This research is funded by the Natural Science Foundation of Fujian Province (2018J01727) and the
scientific research innovation team construction program of Fujian Normal University (IRTL1702).

Conflicts of Interest: The authors declare no conflicts of interest.
Toxins 2018, 10, 346 6 of 8

Funding: This research is funded by the Natural Science Foundation of Fujian Province (2018J01727) and the
scientific research innovation team construction program of Fujian Normal University (IRTL1702).
Conflicts of Interest: The authors declare no conflicts of interest.

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