Introduction
Head and neck squamous cell carcinoma (HNSCC) is the
sixth most common malignant tumor worldwide (1). Its clinicopathological
characteristics include an insidious onset, strong invasiveness and
the liability of recurrence and metastasis with poor prognosis.
Although improvements in therapeutic strategies have been made in
the past 2–3 decades, the overall five-year survival rate remains
almost unchanged. The main reasons for this are considered to be
post-treatment locoregional recurrence, distant metastasis and
inherent therapeutic resistance to chemoradiation and newly
developed molecularly targeted therapy, which is affected by
numerous tumoral microenvironmental factors. Among these factors,
hypoxia in tumors is thought to be closely correlated with the
therapeutic resistance of various types of human cancer.
Hypoxia inducible factor 1α (HIF-1α), a key
regulator of hypoxia, promotes the expression of more than 100
genes related to angiogenesis, cell proliferation, glucose
metabolism, erythropoiesis and cell survival rate (2). Previous studies have demonstrated
that the expression of HIF-1α in HNSCC is associated with a poor
response to radiotherapy and an adverse prognosis (3). As a downstream factor of HIF-1α,
glucose transporter protein-1 (Glut-1; encoded by the SLC2A1 gene
in humans) is ubiquitously expressed in a number of solid tumors.
Previous studies have demonstrated that the suppression of SLC2A1
expression by antisense oligodeoxynucleotides decreases glucose
uptake and inhibits the proliferation of Hep-2 cells. The
expression level of Glut-1 has been correlated with poor prognosis
in a variety of tumors and is responsible for resistance to therapy
(4). The study by Sullu et
al demonstrated that vascular endothelial growth factor (VEGF)
appears to be vital in the metastatic process of HNSCC (5).
Although the expression of HIF-1α, Glut-1 and VEGF
has been investigated under hypoxia in laryngeal carcinoma (LC)
Hep-2 cells, the regulatory mechanisms have not been explored and
thus the role of hypoxia in Hep-2 cells remains unclear. Therefore,
we evaluated the expression of HIF-1α, Glut-1 and VEGF at the
protein and transcriptional levels in Hep-2 cells under hypoxia to
examine their regulation and explore the feasibility of using these
three genes as markers of hypoxia in tumors.
Materials and methods
Cell culture
The present study was conducted at the Department of
Otorhinolaryngology Head and Neck Surgery in Bethune International
Peace Hospital, China, and was approved by the ethics committee of
Bethune International Peace Hospital.
Hep-2 cells (Chinese Acadamy of Science, Shanghai
Institute for Life Sciences, Cell Resource Center, China) were
cultured in complete RPMI-1640 medium (Gibco, Carlsbad, CA, USA)
containing 10% calf serum (Hangzhou Sijiqing Biology Engineering
Materials Co. Ltd., China) under conditions of 37°C, 5%
CO2 and 95% humidity in a carbon dioxide incubator.
Hep-2 cells were divided into 5 experimental and 5 control groups
when they had reached the logarithmic phase. The experimental
groups were cultured under hypoxic conditions (5% CO2,
1% O2 and 94% N2) for 6, 12, 24, 36 and 48 h.
The control groups were cultured under normoxic conditions (5%
CO2, 20% O2 and 75% N2) according
to the durations of the experimental groups. Cells were then
collected for the subsequent detection method following termination
of cultivation.
MTT assay
Hep-2 cells were grown in 96-well plates at a
density of 5×103/200 μl. When all cells had adhered to
the plate, they were incubated under various conditions. Following
incubation, 20 μl MTT (5 mg/ml, Sigma, St. Louis, MO, USA) was
added to each well and left for 4 h prior to adding 150 μl DMSO.
The 96-well plate was then put into an Enzyme-linked Immunosorbent
Detector (Model 550, Bio-Rad, Hercules, CA, USA) with absorbance
values of 490 nm (A490) to detect cell viability. A cell
proliferation curve was graphed according to the absorbance values,
with time values on the X-axis and absorbance values on the
Y-axis.
Immunocytochemistry
For immunohistocytochemical analysis, 6-well plates
were used, in which three small pieces of cover glass were placed.
Single cell suspensions were prepared at a concentration of
1×106 cells/ml using RPMI-1640 medium. A drop of cell
suspension was seeded onto the glass. Cells were grown in an
incubator under normoxic conditions overnight to allow the
adherence of the majority of cells to the cover glass. Each well
was supplemented with 2 ml of RPMI-1640 medium and cultured under
various conditions according to the experimental design. Following
the termination of culturing, the Hep-2 cells were collected for
immunohistocytochemical study. The cover glass was washed with PBS
twice, fixed with cold acetone for 10 min, incubated with 3%
H2O2 for 20 min at room temperature (RT),
incubated with goat serum for 20 min at 37°C, incubated with
primary antibody (rabbit anti-human HIF-1α polyclonal antibody,
rabbit anti-human Glut-1 polyclonal antibody, rabbit anti-human
VEGF polyclonal antibody; Santa Cruz Biotechnology Inc., Santa
Cruz, CA, USA; dilution ratio 1: 50) overnight, washed with PBS,
incubated with goat-anti-rabbit antibody for 15 min at RT and
dropped with horseradish-peroxidase-labeled pronase avidin for 15
min at RT and 3,3′-diaminobenzidine (DAB) reagent for <1 min.
Cells were then redyed with hematoxylin, dehydrated with gradient
alcohol and sealed with neutral resin. For the negative controls,
PBS was used rather than the primary antibodies. Under an optical
microscope (x400), optical density values were measured using Image
Pro Plus Software (Media Cybernetics Inc., Bethesda, MD, USA),
selecting 5 visions randomly on each cover glass.
Western blotting
Equal amounts of Hep-2 cell lysates (30 μg) were
separated using 10–12% SDS-polyacrylamide gel electrophoresis
(SDS-PAGE), transferred to a 0.45 μm PVDF membrane, blocked in 5%
skimmed milk for 2 h at 37°C, incubated with primary antibodies
(dilution ratio 1:200) overnight at 4°C, washed three times in
Tris-buffered saline with 0.25% Tween-20 (TBST), incubated with the
appropriate anti-rabbit secondary antibodies (Beijing Zhongshan
Goldenbridge Bio-technology Co. Ltd., Beijing, China; 1:5,000)
diluted in TBST blocking buffer for 1 h at RT, washed three times
with TBST and detected with PRN2132 Amersham Enhanced
Chemiluminescence (ECL) Plus Western Blotting Detection System (GE
Healthcare Life Sciences, Hatfield, UK). The bands were exposed to
film in a dark chamber and densitometry was evaluated using a gel
image analyzing system (UVP, LLC, Upland, CA, USA).
RT-PCR
Total RNA was isolated from Hep-2 cells with TRIzol
reagent (Invitrogen, Carlsbad, CA, USA) and then reverse
transcribed with the oligo dT primer (Invitrogen). The sequence of
PCR primers used is not shown. The conditions of RT-PCR for HIF-1α
and Glut-1 were as follows: initial denaturation at 94°C for 1 min,
annealing at 60°C for 1 min, polymerization at 72°C for 2 min (35
cycles) and terminal extension at 72°C for 10 min. RT-PCR
conditions for VEGF were as follows: initial denaturation at 94°C
for 1 min, annealing at 56°C for 1 min, polymerization at 72°C for
2.5 min (35 cycles) and terminal extension at 72°C for 10 min. The
products were resolved in 1.5% agarose gels containing 0.5 mg/ml
ethidium bromide. The optical density was assessed using a gel
image analysis system. The ratio of the target gene to the β-actin
gene in each group was semiquantitatively determined.
Statistical analysis
The data are expressed as the mean ± standard
deviation (mean ± SD). One-way ANOVA was used to determine any
statistical differences between the experimental groups. The
Neuman-Keuls multiple comparisons procedure was used to determine
the differences between the two groups. Statistical comparisons
were performed with SPSS 13.0 software for Windows and P<0.05
was considered to indicate statistically significant
differences.
Results
Proliferation of Hep-2 cells
The growth rate of Hep-2 cells was increased under
hypoxic compared with normoxic conditions during the 48-h study
(P<0.05). At the onset of the study, the proliferation rate of
Hep-2 cells under hypoxia was slightly elevated. The difference in
the growth rate between hypoxic and normoxic conditions increased
as time progressed (Fig. 1).
Expression of HIF-1α, Glut-1 and VEGF in
Hep-2 cells
The correlation between the expression of HIF-1α and
Glut-1 or VEGF was first investigated in Hep-2 cells. The
immunocytochemical results revealed that HIF-1α was mainly located
in the cytoplasm or nucleus, Glut-1 was mainly located in the
cytoplasm or cytomembrane and VEGF was located in the cytoplasm.
Under hypoxic conditions, the expression levels of the HIF-1α,
Glut-1 and VEGF proteins were significantly increased (P<0.05).
The protein expression levels reached a peak at approximately 36 h
of hypoxia and then decreased after 48 h. A positive correlation
was observed between protein expression of HIF-1α and Glut-1 or
VEGF in Hep-2 cells (Fig. 2).
Western blot analysis revealed that the expression
of HIF-1α, Glut-1 and VEGF protein increased gradually under
hypoxic conditions and peaked at 36 h, which was consistent with
the immunocytochemical results (Fig.
3).
Effect of expression of HIF-1α on Glut-1
and VEGF genes under hypoxia
RT-PCR results revealed that the mRNA levels of
HIF-1α did not change under hypoxic conditions, while the mRNA
expression levels of Glut-1 and VEGF were upregulated (P<0.05).
The mRNA levels of Glut-1 and VEGF peaked at 36 h (Fig. 4).
Discussion
Hypoxia renders tumor cells more invasive for
metastatic phenotypes and resistant to radiochemotherapy, which is
attributed to the modification of factors related to angiogenesis,
metastasis and resistance to apoptosis as well as therapy. Among
these factors, HIF-1α is significant. The regulation of hypoxia on
HIF-1α expression was considered to occur at the
post-transcriptional level, which reflected its reduced degradation
and elevated binding to DNA (6).
However, other studies have reported that the expression of HIF-1α
mRNA was higher under hypoxia and the regulation of HIF-1α occurred
at the transcriptional level prior to protein alteration (7). The reason that these conclusions are
inconsistent may be a difference of oxygen partial pressure
(PO2) and cell line types. The results of the present
study demonstrated that the majority of the HIF-1α protein was
accumulated during the first 12 h, followed by steady expression
during 12–36 h and finally expression was downregulated at 48 h of
hypoxia. Expression peaked at 36 h. Notably, the mRNA level was
stable under hypoxia. This suggests that the regulation of HIF-1α
under moderately hypoxic conditions (1% oxygen) in Hep-2 cells
occurred at the translational level.
That HIF-1α accumulated in a time-dependent manner
under moderate hypoxia and degraded gradually after 36 h of hypoxia
may be correlated with the following three aspects. Firstly, HIF is
the key regulator of hypoxia in tumor cells and its degradation is
completed by proteasomes via the conjunction of the
O2-dependent HIF prolyl hydroxylase (PHD) enzyme with
its α subunit which is then polyubiquitinated; this is inhibited
when oxygen concentrations decrease below 5%. Hypoxia induces the
reduction of PHD activity, downregulates HIF-1α degradation and
increases its accumulation (6).
Secondly, there is an oxygen-dependent degradation domain (ODD)
located in the 401–603 region of HIF-1α. Under chronically hypoxic
conditions, HIF-1α transformation subordinates to a 2–4 h half-life
and the degradation of proteasomes requires an entire ODD. This
leads to the degradation time of HIF-1α being prolonged. With the
accumulation of protein increasing and its degradation decreasing,
the quantity of HIF-1α reaches saturation. When Hep-2 cells are
cultured continuously, cellular metabolism may be altered leading
to cell death. Thus, in the current study the expression level of
HIF-1α was downregulated after 36 h of hypoxia.
When the tumor microenvironment is under hypoxic
conditions, Glut-1 and glycolytic enzymes are activated by multiple
cancer genes and growth factors. This promotes the increased uptake
and transport of glucose to meet cell energy requirements for fast
proliferation. Immunohistochemical examination has revealed that
Glut-1 is ubiquitously overexpressed in a number of tumors
(8), including breast, thyroid,
hypopharynx, bladder and lung cancer. The expression of Glut-1 is
correlated with a poor prognosis of breast, colorectal and lung
cancer. The expression of Glut-1 is increased in liver cancer,
which promotes tumorigenesis (9).
In the current study, the protein and mRNA levels of Glut-1 were
elevated under hypoxic conditions, followed by HIF-1α accumulation
due to increased expression. This then combines with the promoter
and enhancer on Glut-1 mRNA, leading to Glut-1 transcription to
maintain the metabolism of tumor cells and supply them with a
material foundation for further growth and metastasis. Glut-1 is
mainly regulated by HIF-1α; however, it is also affected by other
regulators (10).
VEGF, a specific mitogen of vascular endothelial
cells, stimulates the formation of new vessels. Its expression is
transcriptionally induced in hypoxic tissues through the action of
HIF-1α and is involved in adaptive processes, including
angiogenesis and neuroprotection (11). The present study revealed that the
protein expression and mRNA levels of VEGF were dynamically
upregulated under hypoxic conditions. However, certain data
demonstrate that VEGF is regulated by multiple intracellular
pathways in a tumor cell and its genesis also occurs in the absence
of HIF-1α. STAT3 is activated under hypoxia by reactive oxygen
species (ROS) which then bind to the promoter of the VEGF gene, as
HIF-1α does under hypoxia (12).
The stress-induced unfolded protein response of the endoplasmic
reticulum also activates VEGF expression (13). It remains to be determined whether
VEGF activation and overexpression are mediated by these pathways
in Hep-2 cells in addition to HIF-1α signaling.
In conclusion, HIF-1α, Glut-1 and VEGF were
co-expressed under hypoxic conditions in human Hep-2 cells. Their
expression level was tightly correlated with oxygen concentration
and culture time. HIF-1α is significant for upregulating Glut-1 and
VEGF expression under hypoxia. HIF-1α, Glut-1 and VEGF jointly act
as an intrinsic marker of tumor hypoxia in LC. Their expressions
are closely related to tumor metabolism and metastasis, which may
help define the biological features and predict the prognosis of
laryngeal squamous carcinoma.
Acknowledgements
The present study was supported in part by the
National Natural Science Research Fund (no. 30572029), China and
the Wu Jieping Medical Research Foundation (no. 320.6750.10121),
China.
References
|
1
|
Jemal A, Siegel R, Ward E, Murray T, Xu J,
Smigal C and Thun MJ: Cancer statistics. CA Cancer J Clin.
56:106–130. 2006.
|
|
2
|
Semenza GL: Targeting HIF-1 for cancer
therapy. Nat Rev Cancer. 3:721–732. 2003. View Article : Google Scholar
|
|
3
|
Koukourakis MI, Giatromanolaki A, Sivridis
E, Pastorek J, Karapantzos I, Gatter KC and Harris AL; Tumour and
Angiogenesis Research Group. Hypoxia-activated tumor pathways of
angiogenesis and pH regulation independent of anemia in
head-and-neck cancer. Int J Radiat Oncol Biol Phys. 59:67–71. 2004.
View Article : Google Scholar : PubMed/NCBI
|
|
4
|
Luo XM, Zhou SH and Fan J: Glucose
transporter-1 as a new therapeutic target in laryngeal carcinoma. J
Int Med Res. 38:1885–1892. 2010. View Article : Google Scholar : PubMed/NCBI
|
|
5
|
Sullu Y, Gun S, Atmaca S, Karagoz F and
Kandemir B: Poor prognostic clinicopathologic features correlate
with VEGF expression but not with PTEN expression in squamous cell
carcinoma of the larynx. Diagn Pathol. 5:352010. View Article : Google Scholar : PubMed/NCBI
|
|
6
|
Huang LE, Gu J, Schau M and Bunn HF:
Regulation of hypoxia-inducible factor 1α is mediated by an
O2-dependent degradation domain via the
ubiquitinproteasome pathway. Proc Natl Acad Sci USA. 95:7987–7992.
1998.
|
|
7
|
Zhong H, Agani F, Baccala AA, Laughner E,
Rioseco-Camacho N, Isaacs WB, Simons JW and Semenza GL: Increased
expression of hypoxia inducible factor-1a in rat and human prostate
cancer. Cancer Res. 58:5280–5284. 1998.PubMed/NCBI
|
|
8
|
Mayer A, Höckel M, Wree A and Vaupel P:
Microregional expression of glucose transporter-1 and oxygenation
status: lack of correlation in locally advanced cervical cancers.
Clin Cancer Res. 11:2768–2773. 2005. View Article : Google Scholar : PubMed/NCBI
|
|
9
|
Amann T, Maegdefrau U, Hartmann A, Agaimy
A, Marienhagen J, Weiss TS, Stoeltzing O, Warnecke C, Schölmerich
J, Oefner PJ, et al: GLUT1 expression is increased in
hepatocellular carcinoma and promotes tumorigenesis. Am J Pathol.
174:1544–1552. 2009. View Article : Google Scholar : PubMed/NCBI
|
|
10
|
Robey IF, Stephen RM, Brown KS, Baggett
BK, Gatenby RA and Gillies RJ: Regulation of the Warburg effect in
early-passage breast cancer cells. Neoplasia. 10:745–756.
2008.PubMed/NCBI
|
|
11
|
Harms KM, Li L and Cunningham LA: Murine
neural stem/progenitor cells protect neurons against ischemia by
HIF-1alpha-regulated VEGF signaling. PLoS One. 5:e97672010.
View Article : Google Scholar : PubMed/NCBI
|
|
12
|
Rathinavelu A, Narasimhan M and Muthumani
P: A novel regulation of VEGF expression by HIF-1α and STAT3 in
HDM2 transfected prostate cancer cells. J Cell Mol Med. Oct
18–2011.(Epub ahead of print).
|
|
13
|
Du H, Li W, Wang Y, Chen S and Zhang Y:
Celecoxib induces cell apoptosis coupled with up-regulation of the
expression of VEGF by a mechanism involving ER stress in human
colorectal cancer cells. Oncol Rep. 26:495–502. 2011.PubMed/NCBI
|
