Contents
Introduction
Measuring HNSCC hypoxia
Molecular markers of hypoxia
Strategies for modifying tumor hypoxia
Conclusion
Introduction
Head and neck squamous cell carcinoma (HNSCC) is the
eighth most common cancer in the United States, accounting for
approximately 3% of all cancers. In 2010, physicians diagnosed
approximately 49,260 new cases of HNSCC and 11,480 patients
succumbed to the disease in the United States (1). Despite advances in surgical
techniques, radiotherapy, and chemotherapy, 5-year survival rates
in patients with late-stage HNSCC have not improved significantly
over the past decades. In particular, the 3- to 5-year survival
rates in patients with T3 or T4 HNSCC have remained poor (20–30%)
(2). Given this poor survival
rate, current intensive research is directed towards improving
outcomes of HNSCC by combining alternative molecular-targeted
therapy with conventional therapy.
Hypoxia is common in HNSCC cells and is an important
cancer-aggravating microenvironmental factor that contributes to
malignant behaviors such as the acquisition of antiapoptotic
ability by cancer cells, as well as tumor progression, invasion,
metastasis, and resistance to chemotherapy and radiotherapy
(3). It has been reported that
hypoxic HNSCC cells are approximately three times more
radioresistant than well-oxygenated cells as radiation damage is
mainly induced by the generation of highly reactive free radicals
in the presence of oxygen, causing DNA damage and, consequently,
cell death. Mottram (4) first
described the radioresistance of hypoxic cells, and Thomlinson and
Gray (5) confirmed this
resistance. Specifically, in the latter study, the authors
suggested that the presence of quiescent but viable hypoxic cancer
cells is able to limit the success of radiotherapy. Therefore,
tumor hypoxia may be a prognostic indicator for HNSCC and may play
a role in selection of therapeutic strategies for this cancer.
Measuring HNSCC hypoxia
Numerous studies have focused on the role of tumor
hypoxia in various types of cancer. Methods used to measure tumor
hypoxia include direct placement of intratumoral oxygen
microelectrodes, the comet assay, and the systemic administration
of drugs followed by histopathologic analysis of tumor samples. In
particular, oxygen microelectrodes measure intratumoral oxygen
tension, with a pO2 value less than 2.5 mmHg considered
to be clinically significant and associated with poor local control
of hypoxia (6). However,
pO2 results can be misleading, as readings vary
according to the location of the microelectrodes inside the tumor.
Additionally, these microelectrodes can only be placed in
accessible tumors. The advantage of the comet assay is its ability
to measure DNA damage due to irradiation in hypoxic cells. Although
a correlation exists between necrosis and hypoxia, the number of
viable hypoxic cells has greater prognostic significance than the
number of necrotic cells. The systemic administration of drugs such
as nitroimidazoles, which diffuse easily into hypoxic cells due to
drug solubility and low metabolism in tumor cells prior to biopsy
or resection, can be used to quantify hypoxic HNSCC cells. Hypoxic
cells are then identified using immunofluorescence assays or flow
cytometry.
The imaging modalities used to identify hypoxia
include 18F-labeled fluorodeoxyglucose
(18F-FDG) positron emission tomography (PET), detection
of radiolabeled nitroimidazoles using single-photon emission
computed tomography, and dynamic contrast-enhanced magnetic
resonance imaging. Studies examining the ability of
18F-FDG PET to detect tumor hypoxia have had mixed
results (7,8). Tracers used in PET instead of
18F-FDG include metal-labeled markers such as
copper-labeled diacetyl-bis(N4methylthiosemicarbazone).
Dynamic contrast-enhanced magnetic resonance imaging can also be
used to assess tumor perfusion and, thus, indirectly assess tumor
oxygenation. Evidence regarding its usefulness in predicting
response to cervical cancer and HNSCC to radiotherapy has been
reported (9,10).
Molecular markers of hypoxia
Recent studies have identified molecular markers of
hypoxia that are promising therapeutic targets in HNSCC patients
(11). Endogenous molecular
markers include hypoxia-inducible factor (HIF)-1α, HIF-2α, glucose
transporter 1 (Glut-1), and carbonic anhydrase IX. HIF-1α and
HIF-2α are transcription factors that mediate the cell response to
hypoxia and are highly expressed in solid tumors containing hypoxic
regions (12). These two factors
upregulate the expression of vascular endothelial growth factor,
Glut-1, and carbonic anhydrase IX, causing their intracellular
levels to increase within 2 min of exposure to hypoxia.
Overexpression of HIF-1α in HNSCC cells is positively correlated
with local tumor aggressiveness, increased tumor angiogenesis, poor
prognosis (13,14), and resistance to radiotherapy and
chemotherapy (15,16). The correlation between the
expression of HIF-1α and resistance to chemotherapy may be
explained by the results of in vivo studies showing that the
sensitivity of tumors to alkylating agents may depend on Glut-1
expression in cancer cells (17).
Strategies for modifying tumor hypoxia
A number of hypoxia-modifying strategies have been
examined, with little to moderate success, including the use of
hyperbaric oxygen therapy, carbogen, nicotinamide with
radiotherapy, tirapazamine (a bioreductive agent with selective
cytotoxicity in hypoxic cells) with chemoradiation, and
radiosensitizers including nimorazole with radiotherapy (18).
Several molecular strategies have been suggested in
the targeting of cell processes for the modification of hypoxia
through the direct or indirect regulation of HIF-1α expression in
tumor cells (19). Investigators
pursuing direct regulation have identified and investigated small
molecular targets, HIF-1α, and examined their use as therapeutic
agents for hypoxia. One of these molecules,
S-2-amino-3-(4′-N,N,-bis[2-chloroethyl] amino)phenyl propionic acid
N-oxide dihydrochloride (PX-478), reduces the constitutive and
hypoxia-induced expression of HIF-1α in cancer cells and inhibits
the expression of vascular endothelial growth factor and Glut-1.
Inhibition of tumor growth induced by treatment with this molecule
appears to correlate with the inhibition of glucose metabolism
rather than of angiogenesis (20).
Thus, PX-478 has been assessed in phase 1 studies (21).
Currently, topotecan is used in chemotherapy for
small-cell lung cancer and ovarian cancer (21). However, combination of the HIF-1α
inhibitor with conventional chemotherapeutic agents or with an
emerging molecular-targeted agent may have greater clinical
efficacy against hypoxia than either therapy alone (13). Investigators studying the indirect
regulation of HIF-1α expression in cancer cells have reported that
hypoxia-responsive transcription factors and signaling mechanisms
that lead to activation of these factors, including the
phosphatidylinositol 3-kinase (PI3K)/protein kinase B
(Akt)/mammalian target of rapamycin (mTOR) signaling axis and Janus
kinase/signal transducer and activator of transcription (STAT)
signaling pathway, may be targets for hypoxia therapy (13). STAT3 and HIF-1 activate the
vascular endothelial growth factor (VEGF) gene in response to
PI3K/Akt/mTOR signaling pathways. For example, the STAT3 inhibitor
Stattic has been reported to inhibit STAT3 activation induced by
the phosphorylation and concurrent HIF-1 expression in HNSCC cells,
leading to tumor supression and enhanced tumor radio-sensitivity
(22). Therefore, STAT3 is a
potential molecular therapeutic target for HNSCC, particularly in
hypoxic environments.
Conclusion
Hypoxia in HNSCC must be addressed to improve
treatment efficacy. Increased knowledge of the molecular biology of
hypoxia is likely to enhance its detection, assessment of its
relevance, and overcoming its negative influence in treatment of
HNSCC.
Acknowledgements
Makoto Adachi is funded by the Uehara
Memorial Foundation Postdoctoral Fellowship and the Japan Society
for the Promotion of Science Postdoctoral Fellowship for Research
Abroad. This review is funded in part by the MD Anderson Cancer
Center Support Grant CA016672.
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