1. Introduction
Proteases represent approximately 2.8% of the
proteins expressed by the human genome. They are commonly involved
in degradation pathways eliminating unwanted and defective
proteins. Researchers have been studying the effects of proteases
on cancer development, aiming to develop new anticancer therapies
(1-3).
Proteases are a large group of enzymes that catalyze the cleavage
of peptide bonds. Cathepsin S (Cat S) is a cysteine protease found
more frequently in lysosomes of hematopoietic cells, but it may
also be segregated in the extracellular environment (4-7).
Studies have demonstrated that the inhibition of Cat
S results not only in attenuation of angiogenesis, but also in
increased apoptosis and reduction of tumor volume and invasion.
These effects indicate a potential relevant role for Cat S in tumor
growth and progression, and this molecule may be a possible target
for cancer treatment (3,4,8).
The literature on the association between Cat S and
gastrointestinal neoplasms is scarce, with even fewer studies
assessing specifically its association with GC. The aim of the
present study was to review the currently available information
regarding Cat S and the occurrence and progression of GC, with the
purpose of developing future perspectives for using Cat S as a
possible therapeutic target for this malignancy.
2. Gastric cancer
GC is the fifth most frequently diagnosed cancer and
the third leading cause of cancer-related mortality worldwide
(9). The incidence of GC varies
according to different geographic regions. Approximately 60% of
gastric neoplasms occur in developing countries. The highest
incidence is observed in Eastern Asia, Eastern Europe and the
Andean region of South America, whereas the lowest rates are
encountered in North America, Northern Europe, Southeast Asia and
the majority of African countries (10,11).
Statistical data have been demonstrating a declining
incidence of GC, particularly in USA, England, and other developed
countries (11). However, an
increasing incidence is observed in patients <30 years of age,
with the possible implication of different molecules, pathways and
epigenetic mechanisms (12).
The GC-related mortality rates are considerably high
worldwide, with a mean 5-year survival rate of 21% in Europe and
18% in the USA. The highest rates are reported in Osaka, Japan,
with a mean 5-year survival rate of 47% (10).
The majority of GCs occur sporadically due to
complex interactions between environmental and ethnic factors.
However, approximately 1-3% display an inherited familial
component. Patients with germline mutations in tumor protein
p53 (Li-Fraumeni syndrome), breast cancer 2 gene and
cadherin-1, in particular, are at an increased risk of developing
GC (13).
Infection by H. pylori is considered the most
important risk factor for the development of GC, particularly
gastric adenocarcinoma (14).
Although it is clear that H. pylori is the most frequent
predisposing agent for GC, the precise molecular mechanisms
underlying the development of this neoplasm in reaction to H.
pylori infection have not been clearly determined. However, the
increased cellular replication and the constant attraction of
polymorphonuclear leukocytes are well known events that appear to
exert carcinogenic effects (15,16).
Amedei et al (17) reported
that the secreted peptidyl prolyl cis, trans-isomerase of H.
pylori is able to drive gastric Th17 response in patients with
distal GC. Therefore, they inferred that H. pylori may be
linked to GC through the pro-inflammatory low cytotoxic response,
matrix degradation and pro-angiogenic pathways (17).
Several oncogenes, tumor suppressor genes and
metastasis-related genes have been implicated in GC (18). Some of the dysregulated genes in GC,
including p53, Kirsten rat sarcoma 2 viral oncogene homolog,
transforming growth factor receptor-2 and catenin β-1, may be
implicated in the development of a wide variety of other tumors.
Other genes, such as fibroblast growth factor receptor-2 and MET
proto-oncogene, are more specific to GC. Among the mutated genes or
those with increased expression in GC, some, such as human
epidermal growth factor receptor-2 (HER2/NEU),
cyclooxygenase-2 (COX2) and epidermal growth factor receptor
(EGFR), have been investigated as possible targets for GC
therapy (19,20). It has been demonstrated that
trastuzumab, an inhibitor of HER2/NEU, can affect the growth
of HER2/NEU-overexpressing GC cells (21). GC with COX2 overexpression has
been associated with lymphatic metastasis, and the use of
COX2-specific inhibitors, such as celecoxib, are under
investigation as a possible intervention for advanced disease
(19). Regarding EGFR, it has
been observed that increased expression of this receptor is
associated with worse prognosis in GC. Its selective inhibition by
gefitinib has shown promising results for metastatic disease
(22).
3. Cathepsin S and carcinogenesis
During the development and progression of tumors,
one of the most important events is local invasion, which is
mediated by the degradation of the extracellular matrix (ECM), and
the proteases involved in this process are being increasingly
identified (23). Invasive tumor
cells and their microenvironment are enriched with a wide range of
proteases (4).
Νew therapeutic strategies and biomarkers have been
identified for the treatment and diagnosis of malignant tumors.
Among these, a group of proteases, the lysosomal cysteine
cathepsins (e.g., Cat S), appear to be of extreme relevance. The
inhibition of Cat S using a selective monoclonal antibody (Fsn0503)
has been shown to be beneficial, acting against colorectal,
prostatic and breast carcinoma invasion, and it has also achieved
attenuation of angiogenesis in several types of tumors (24). The in vivo inhibition of Cat S
by Fsn0503 has also achieved a significant decrease in colorectal
tumor growth in murine models, not only as an isolated agent
(24), but also in combination with
chemotherapy (25,26).
The involvement of Cat S in carcinogenesis appears
to be related to apoptosis, autophagy, angiogenesis, and cell
migration and invasion.
Apoptosis
Lysosomes are essential organelles in the process of
apoptosis, and cathepsins are important executors of
lysosome-mediated apoptosis. Cat S assists with the essential
mediation of apoptotic signaling to release cathepsins to the
cytosol. Apoptosis induced by Cat S occurs through different
apoptotic pathways, including the intrinsic pathway (mitochondrial
death) and the extrinsic pathway (death receptor). The former is
controlled by members of the B-cell lymphoma-2 (Bcl-2) family, such
as Bcl-2 and Bcl-2-associated death promoter. In the latter, death
receptors on the plasma membrane activate the tumor necrosis factor
receptor 1 and Fas/CD95. However, the specific molecular mechanisms
implicated in lung cancer, GC and prostate cancer are unclear
(27,28).
Autophagy
Cat S is associated with autophagy in cancer cells.
This may be explained by the association between lysosomes and Cat
S. Targeting Cat S may induce autophagy in cancer cells, such as
nasopharyngeal cancer, colon adenocarcinoma, oral-epidermoid
carcinoma, alveolar basal epithelial and human squamous carcinoma
cells. Therefore, the inhibition and induction of autophagy
mediated by Cat S is not cell-specific, and targeting Cat S may
induce autophagy in GC (27,29).
Angiogenesis
It has been observed that Cat S plays an important
role in angiogenesis, which is a crucial part of tumor development
and a fundamental step in the transition of tumors from a benign to
a malignant state (27).
In an experiment on human umbilical vein endothelial
cells (HUVECs), it was observed that the vascular endothelial
growth factor (VEGF) stimulated HUVEC capillary tube formation,
whereas the addition of three specific Cat S inhibitors suppresses
the proteolytic activity of Cat S, resulting in significant
reduction of VEGF-induced capillary-like tube development (30).
In another experiment, suppressed VEGF secretion and
restrained HUVEC tube formation in human hepatocellular carcinoma
was achieved through targeting Cat S by small interfering RNA
(28). However, the precise
molecular mechanisms through which Cat S interferes with
angiogenesis remain elusive (27).
Invasion and migration
Cat S is of paramount importance in cell migration
and invasion. It has been observed that silencing Cat S by specific
siRNAs leads to inhibition of GC cell invasion (31). The same was observed for other cancer
cells, such as hepatocellular carcinoma, lung adenocarcinoma, and
skin melanoma cells. Therefore, Cat S may be an important factor
for containing malignant cell invasion and migration (27,28).
The expression of Cat S was found to be increased in
several types of cancer, including GC. One of its main sources are
tumor-associated macrophages (27,32).
Therefore, Cat S may be of value not only as a therapeutic target,
but also as a prognostic marker, as it is closely associated with
the occurrence of metastasis (3,32).
4. Cathepsin S and gastric cancer
The results previously reported in the literature
regarding the inhibition of Cat S in different gastrointestinal
neoplasms are summarized in Table I.
The data on the experimental use of Cat S inhibitors and its
outcomes, either in vivo or in vitro, for
gastrointestinal cancer development are summarized. Of note, only a
few studies have assessed the role of this molecule in
gastrointestinal cancers, and even fewer in GC, which is the main
objective of the present study.
 | Table ICathepsin S as an inhibitor of
gastrointestinal malignant neoplasms. |
Table I
Cathepsin S as an inhibitor of
gastrointestinal malignant neoplasms.
| Tumor site | Testing | Role | Cell line | Results of
cathepsin S inhibitors | Author (Refs) |
|---|
| Colorectal | In
vitro | Increased
expression, associated with tumor growth and invasion | Fsn0503h, MC38 | Cytotoxic effect
(antibody-dependent cytotoxicity) in 22% of the tumor cells, in
addition to the inhibition of invasion and angiogenesis | Wilkinson et
al (7) |
| | In vivo | | | | Burden et al
(25) |
| | | | | | Burden et al
(26) |
| | | | | | Kwok et al
(32) |
| | | | | | Small et al
(30) |
| Pancreatic | In vivo, in
vitro | Increased
expression, associated with tumor growth | RIP1-Tag2 | Inhibition of tumor
growth and angiogenesis | Wang et al
(37) |
| Hepatocellular | In vivo | Induced apoptosis
Increased expression, associated with growth, invasion and
metastasis | MHCC97-H | CTSS silencing with
lentivirus-mediated RNAi can induce significant apoptosis and
chemosensitivity in MHCC97-H cells | Lee et al
(38) |
| | In
vitro | | | | Wang et al
(39) |
| Gastric | In
vitro | Increased
expression, associated with tumor invasion and metastasis | MFEN45 and
MKN7 | CTSS inhibitors may
be able to impede invasion and migration of gastric cancer
cells | Yang et al
(33) |
| | | | | | Liu et al
(31) |
Regarding the occurrence of GC, Cat S is associated
with one of the hallmarks of tumor development, namely local
invasion. This process occurs due to the fact that Cat S is able to
degrade the ECM, modulate inflammation and the immune response, as
well as regulate other carcinogenic factors (27,33).
Cat S acts as a regulator of signaling pathways
including: i) Tyrosine kinase receptors, such as c-Met and AXL
(33). Cat S may be necessary for
the proteolytic maturation and secretion of c-Met into the
extracellular compartment of GC cells; ii) peptidases, including
members of the cathepsin family (e.g., Cat D), matrix
metallopeptidases and kallikrein families (33). Cat D and matrix metallopeptidases are
associated with cancer metastasis and recurrence (33), and they have the ability to digest
the ECM that otherwise impedes cancer cell invasion; iii)
chemokines/cytokines, such as IL-11 and CXCL16. CXCL16 is a
molecule essential for the development of peritoneal carcinomatosis
in GC (33), whereas IL-11 is
required for GC development; iv) Cytoskeletal proteins and adhesion
molecules, such as cortactin (CTTN) and integrins,
respectively (33). CTTN and
integrin α6β4 play important roles in cell-cell and focal adhesion,
thereby affecting cell migration (33). The inhibition of Cat S leads to
diminished expression of these molecules; v) proteins from
HFE145, MKN7 and MKN45 (33). When compared with normal cells, Cat S
expression is increased in the GC cells MKN7 and MKN45(33).
The members of the cysteine cathepsin family
displaying increased expression in GC are Cat B, E, K, L, S, X and
Z. Cat S is the only one among the cysteine cathepsins the
expression of which is associated with antigen-presenting cells.
Therefore, as regards protein processing in the extracellular
microenvironment, Cat S is of higher physiological importance
compared with the remaining family members (34-36).
Invasive methods, such as endoscopy and biopsy, are
used for GC diagnosis. Certain tumor markers may also prove useful
in the diagnosis and follow-up of this disease, such as
carcinoembryonic antigen (CEA), carbohydrate antigen (CA) 72-4 and
CA 19-9. However, their sensitivity is not sufficient to enable
diagnosis at the early stages (31).
Therefore, there is a pressing need for biomarkers with higher
specificity and sensitivity to enable early, non-invasive
diagnosis, and to monitor the progression of GC (3).
The diagnostic value of serum Cat S has been found
to have a specificity similar to the conventionally used markers
CEA, CA 72-4 and CA 19-9, but with a higher sensitivity. The
combination of serum Cat S and these traditional markers has
demonstrated the best results, with specificity and sensitivity of
91.2 and 72.6%, respectively (31).
5. Conclusion
As regards the occurrence of GC, increased
expression of Cat S, which is a member of a large group of
extracellular proteases, was observed; in addition, the inhibition
of Cat S was shown to suppress migration and invasion of gastric
neoplastic cells. Therefore, it may be inferred that Cat S may hold
promise as a biomarker for the diagnosis and prognosis of GC, in
addition to being a possible therapeutic target to control disease
progression.
However, due to the scarcity of the currently
available literature on the association between Cat S and GC, more
studies, particularly clinical trials and prospective studies, are
required to provide more solid data and elucidate the true value of
Cat S, not only as a diagnostic and prognostic marker, but also as
an effective therapeutic target, in the hope of achieving better
disease control and improving the life quality and survival rate of
GC patients.
Acknowledgements
Not applicable.
Funding
No funding was received.
Availability of data and materials
Not applicable.
Authors' contributions
ACDC, AABF and JLF were involved in the initial
design of the study and conception of the project. FSC, LARM, MARA
and CRM helped with the literature research and the writing of the
manuscript. ACDC and AABF helped draft the manuscript. AABF and JLF
supervised the study. FSC, LARM, JLF were responsible for the final
revision. All authors read and approved the final manuscript.
Ethics approval and consent to
participate
Not applicable.
Patient consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing
interests.
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